US20130105304A1 - System and High Surface Area Electrodes for the Electrochemical Reduction of Carbon Dioxide - Google Patents

System and High Surface Area Electrodes for the Electrochemical Reduction of Carbon Dioxide Download PDF

Info

Publication number
US20130105304A1
US20130105304A1 US13/724,988 US201213724988A US2013105304A1 US 20130105304 A1 US20130105304 A1 US 20130105304A1 US 201213724988 A US201213724988 A US 201213724988A US 2013105304 A1 US2013105304 A1 US 2013105304A1
Authority
US
United States
Prior art keywords
compartment
cathode
catholyte
surface area
high surface
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Abandoned
Application number
US13/724,988
Inventor
Jerry J. Kaczur
Theodore J. Kramer
Paul Masztrik
Kunttal Keyshar
Zbigniew Twardowski
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Liquid Light Inc
Original Assignee
Liquid Light Inc
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Liquid Light Inc filed Critical Liquid Light Inc
Priority to US13/724,988 priority Critical patent/US20130105304A1/en
Assigned to LIQUID LIGHT, INC. reassignment LIQUID LIGHT, INC. ASSIGNMENT OF ASSIGNORS INTEREST (SEE DOCUMENT FOR DETAILS). Assignors: KRAMER, Theodore J., MAJSZTRIK, PAUL, KACZUR, JERRY C., TWARDOWSKI, ZBIGNIEW, KEYSHAR, KUNTTAL
Publication of US20130105304A1 publication Critical patent/US20130105304A1/en
Assigned to LIQUID LIGHT, INC. reassignment LIQUID LIGHT, INC. ASSIGNMENT OF ASSIGNORS INTEREST (SEE DOCUMENT FOR DETAILS). Assignors: TWARDOWSKI, ZBIGNIEW, KEYSHAR, KUNTTAL, KACZUR, JERRY J., KRAMER, Theodore J., MAJSZTRIK, PAUL
Assigned to LIQUID LIGHT, INC. reassignment LIQUID LIGHT, INC. CORRECTIVE ASSIGNMENT TO CORRECT THE TO REMOVE AN INCORRECT APPLICATION NUMBER PREVIOUSLY RECORDED ON REEL 030286 FRAME 0737. ASSIGNOR(S) HEREBY CONFIRMS THE TO CORRECT THE APPLICATION NUMBER FROM 13/724,998 TO 13/724,988. Assignors: TWARDOWSKI, ZBIGNIEW, KEYSHAR, KUNTTAL, KACZUR, JERRY J., KRAMER, Theodore J., MAJSZTRIK, PAUL
Priority to PCT/US2013/053558 priority patent/WO2014042782A1/en
Priority to US14/427,934 priority patent/US9873951B2/en
Priority to PCT/US2013/060004 priority patent/WO2014043651A2/en
Priority to US14/471,152 priority patent/US10287696B2/en
Abandoned legal-status Critical Current

Links

Images

Classifications

    • C25B11/0478
    • CCHEMISTRY; METALLURGY
    • C25ELECTROLYTIC OR ELECTROPHORETIC PROCESSES; APPARATUS THEREFOR
    • C25BELECTROLYTIC OR ELECTROPHORETIC PROCESSES FOR THE PRODUCTION OF COMPOUNDS OR NON-METALS; APPARATUS THEREFOR
    • C25B15/00Operating or servicing cells
    • C25B15/08Supplying or removing reactants or electrolytes; Regeneration of electrolytes
    • CCHEMISTRY; METALLURGY
    • C25ELECTROLYTIC OR ELECTROPHORETIC PROCESSES; APPARATUS THEREFOR
    • C25BELECTROLYTIC OR ELECTROPHORETIC PROCESSES FOR THE PRODUCTION OF COMPOUNDS OR NON-METALS; APPARATUS THEREFOR
    • C25B11/00Electrodes; Manufacture thereof not otherwise provided for
    • C25B11/04Electrodes; Manufacture thereof not otherwise provided for characterised by the material
    • C25B11/051Electrodes formed of electrocatalysts on a substrate or carrier
    • C25B11/073Electrodes formed of electrocatalysts on a substrate or carrier characterised by the electrocatalyst material
    • C25B11/091Electrodes formed of electrocatalysts on a substrate or carrier characterised by the electrocatalyst material consisting of at least one catalytic element and at least one catalytic compound; consisting of two or more catalytic elements or catalytic compounds
    • CCHEMISTRY; METALLURGY
    • C25ELECTROLYTIC OR ELECTROPHORETIC PROCESSES; APPARATUS THEREFOR
    • C25BELECTROLYTIC OR ELECTROPHORETIC PROCESSES FOR THE PRODUCTION OF COMPOUNDS OR NON-METALS; APPARATUS THEREFOR
    • C25B15/00Operating or servicing cells
    • CCHEMISTRY; METALLURGY
    • C25ELECTROLYTIC OR ELECTROPHORETIC PROCESSES; APPARATUS THEREFOR
    • C25BELECTROLYTIC OR ELECTROPHORETIC PROCESSES FOR THE PRODUCTION OF COMPOUNDS OR NON-METALS; APPARATUS THEREFOR
    • C25B3/00Electrolytic production of organic compounds
    • C25B3/20Processes
    • C25B3/25Reduction
    • C25B9/10
    • CCHEMISTRY; METALLURGY
    • C25ELECTROLYTIC OR ELECTROPHORETIC PROCESSES; APPARATUS THEREFOR
    • C25BELECTROLYTIC OR ELECTROPHORETIC PROCESSES FOR THE PRODUCTION OF COMPOUNDS OR NON-METALS; APPARATUS THEREFOR
    • C25B9/00Cells or assemblies of cells; Constructional parts of cells; Assemblies of constructional parts, e.g. electrode-diaphragm assemblies; Process-related cell features
    • C25B9/17Cells comprising dimensionally-stable non-movable electrodes; Assemblies of constructional parts thereof
    • C25B9/19Cells comprising dimensionally-stable non-movable electrodes; Assemblies of constructional parts thereof with diaphragms
    • CCHEMISTRY; METALLURGY
    • C25ELECTROLYTIC OR ELECTROPHORETIC PROCESSES; APPARATUS THEREFOR
    • C25BELECTROLYTIC OR ELECTROPHORETIC PROCESSES FOR THE PRODUCTION OF COMPOUNDS OR NON-METALS; APPARATUS THEREFOR
    • C25B9/00Cells or assemblies of cells; Constructional parts of cells; Assemblies of constructional parts, e.g. electrode-diaphragm assemblies; Process-related cell features
    • C25B9/17Cells comprising dimensionally-stable non-movable electrodes; Assemblies of constructional parts thereof
    • C25B9/19Cells comprising dimensionally-stable non-movable electrodes; Assemblies of constructional parts thereof with diaphragms
    • C25B9/23Cells comprising dimensionally-stable non-movable electrodes; Assemblies of constructional parts thereof with diaphragms comprising ion-exchange membranes in or on which electrode material is embedded

Definitions

  • the present disclosure generally relates to the field of electrochemical reactions, and more particularly to methods and/or systems for electrochemical reduction of carbon dioxide using high surface area electrodes.
  • a mechanism for mitigating emissions is to convert carbon dioxide into economically valuable materials such as fuels and industrial chemicals. If the carbon dioxide is converted using energy from renewable sources, both mitigation of carbon dioxide emissions and conversion of renewable energy into a chemical form that can be stored for later use may be possible.
  • the present invention is directed to using high surface area electrodes and particular electrolyte solutions to produce single carbon (C1) chemicals, including formic acid, and multi-carbon (C2+) based chemicals (i.e., chemicals with two or more carbon atoms in the compound).
  • C1 chemicals including formic acid, and multi-carbon (C2+) based chemicals (i.e., chemicals with two or more carbon atoms in the compound).
  • C2+ multi-carbon
  • FIG. 1 is a flow diagram of a preferred electrolyzer system for the reduction of carbon dioxide in accordance with an embodiment of the present disclosure
  • FIG. 2 is a flow diagram of a preferred electrochemical acidification system
  • FIG. 3 is a flow diagram of another preferred system for the electrochemical reduction of carbon dioxide
  • FIG. 4 is a flow diagram of another preferred electrochemical acidification system incorporating bipolar membranes
  • FIG. 5 is flow diagram of another preferred electrochemical electrolyzer system incorporating an ion exchange compartment for the reduction of carbon dioxide.
  • FIG. 6 is a flow diagram of a nano-filtration system in accordance with an embodiment of the present disclosure.
  • FIG. 7 is a chart illustrating cumulative yield of formate over time in accordance with an embodiment described with reference to Example 1 of the present disclosure
  • FIG. 8 is a chart illustrating cumulative yield of formate over time in accordance with an embodiment described with reference to Example 2 of the present disclosure
  • FIG. 9 is a chart illustrating cumulative yield of formate over time in accordance with an embodiment described with reference to Example 3 of the present disclosure.
  • FIG. 10 is a chart illustrating cumulative yield of formate over time in accordance with an embodiment described with reference to Example 4 of the present disclosure
  • FIG. 11 is a chart illustrating cumulative formate yield versus time in accordance with an embodiment described with reference to Example 9 of the present disclosure
  • FIG. 12 is a chart illustrating formate concentration versus time in accordance with an embodiment described with reference to Example 9 of the present disclosure
  • FIG. 13 is a chart illustrating cumulative formate yield versus time in accordance with an embodiment described with reference to Example 10 of the present disclosure
  • FIG. 14 is a chart illustrating formate concentration versus time in accordance with an embodiment described with reference to Example 10 of the present disclosure
  • FIG. 15 is a chart illustrating operating cell voltage versus time in accordance with an embodiment described with reference to Example 11 of the present disclosure
  • FIG. 16 is a chart illustrating catholyte formate concentration versus time in accordance with an embodiment described with reference to Example 11 of the present disclosure
  • FIG. 17 shows a scanning electron microscope (SEM) image of the electroless indium coating on tin-plated copper fiber cathode used in Example 11 of the present disclosure
  • FIG. 18 shows an SEM image of an electroless indium coating on a treated carbon fiber material
  • FIG. 19 is a chart illustrating formate current efficiency versus time in accordance with an embodiment described with reference to Example 11 of the present disclosure.
  • FIG. 20 is a chart illustrating catholyte pH versus time in accordance with an embodiment described with reference to Example 11 of the present disclosure
  • FIG. 21 is a chart illustrating formate current efficiency versus time in accordance with an embodiment described with reference to Example 12 of the present disclosure
  • FIG. 22 is a chart illustrating catholyte formate concentration versus time in accordance with an embodiment described with reference to Example 12 of the present disclosure.
  • FIG. 23 is a chart illustrating catholyte pH versus time in accordance with an embodiment described with reference to Example 12 of the present disclosure.
  • an electrochemical system that converts carbon dioxide to organic products including formate and formic acid.
  • a cathode comprising a high surface area three dimensional material, an acidic anolyte, and a catholyte comprising bicarbonate facilitates the process.
  • the electrolyzer system 100 may be utilized for the electrochemical reduction of carbon dioxide to organic products or organic product intermediates.
  • the electrolyzer system 100 reduces carbon dioxide to an alkali metal formate, such as potassium formate.
  • the electrolyzer system 100 generally includes an electrolyzer 102 , an anolyte recycle loop 104 , and a catholyte recycle loop 106 .
  • the electrolyzer system 100 may include as process feeds/inputs carbon dioxide, a catholyte comprising bicarbonate (preferably potassium bicarbonate, but other bicarbonate-based compounds are contemplated instead of or in addition to potassium bicarbonate), and an acidic anolyte (preferably sulfuric acid, but may include other acids, instead of, or in addition to sulfuric acid).
  • a catholyte comprising bicarbonate (preferably potassium bicarbonate, but other bicarbonate-based compounds are contemplated instead of or in addition to potassium bicarbonate)
  • an acidic anolyte preferably sulfuric acid, but may include other acids, instead of, or in addition to sulfuric acid.
  • the product of the electrolyzer system 100 is generally an alkali metal formate, such as potassium formate, and may include excess catholyte, carbon dioxide, hydrogen, oxygen, and/or other unreacted process inputs.
  • the electrolyzer 102 generally includes an anode compartment 108 and a cathode compartment 110 , and may further include a cation exchange membrane 112 to separate the anode compartment 108 from the cathode compartment 110 .
  • the anode compartment 108 includes an anode 114 suitable to oxidize water.
  • the anode 114 is a titanium anode having an anode electrocatalyst coating which faces the cation exchange membrane 112 .
  • the anode 114 may include an anode mesh screen 116 that includes a folded expanded titanium screen with an anode electrocatalyst coating.
  • the anode mesh screen 116 may provide spacing and contact pressure between the anode 114 and the cation exchange membrane 112 .
  • the anode 114 may also include one or more electrical current connection posts (not shown) on a backside of the anode 114 .
  • the cathode compartment 110 generally includes a cathode 118 mounted within the cathode compartment 110 .
  • the cathode 118 preferably includes a metal electrode with an active electrocatalyst layer on a front surface of the cathode 118 facing the cation exchange membrane 112 , and may include one or more electrical current conduction posts (not shown) on a backside of the cathode 118 .
  • the cathode 118 preferably includes a high surface area cathode structure 120 .
  • the high surface area cathode structure 120 may be mounted between the cation exchange membrane 112 and the cathode 118 for conducting electrical current into the high surface area cathode structure 120 .
  • the interface between the high surface area cathode structure 120 and the cation exchange membrane 112 may include an insulator screen (not shown), such as a thin expanded plastic mesh insulator screen to minimize direct contact between the high surface area cathode structure 120 and the cation exchange membrane 112 .
  • an insulator screen such as a thin expanded plastic mesh insulator screen to minimize direct contact between the high surface area cathode structure 120 and the cation exchange membrane 112 .
  • the anode compartment 108 generally includes an anode feed stream 122 that includes a dilute acid anolyte solution.
  • the anode feed stream 122 may enter a bottom of the anode compartment 108 to flow by a face of the anode 114 and through the anode mesh screen 116 .
  • the reaction in the anode compartment 108 may include deriving oxygen (O 2 , i.e., gaseous oxygen) and hydrogen ions (H + ) or protons from the oxidation of water at an applied current and voltage potential.
  • the hydrogen ions or protons are generally available for the reactions within the cathode compartment 110 via the cation exchange membrane 112 .
  • the gaseous oxygen and other liquids leaving the anode compartment 108 of the electrolyzer 102 leave as anode exit stream 124 .
  • the anode exit stream 124 may be monitored by a temperature sensor 126 a and may flow to an anolyte disengager 128 suitable for separating the oxygen from the anode exit stream 124 .
  • the anolyte disengager 128 may process the anode exit stream 124 into an oxygen stream 130 , an anolyte recycle stream 132 , and an anolyte overflow stream 134 .
  • the oxygen stream 130 may be vented from the anolyte disengager 128 .
  • the anolyte stream 132 may be combined with water (preferably deionized water) from a water source 136 and with acid (preferably sulfuric acid) from an acid source 138 .
  • the water source 136 and the acid source 138 in the anolyte recycle loop 104 may maintain anolyte acid strength and volume for the anode feed stream 122 .
  • the temperature of the anode feed stream 122 may be regulated by a heat exchanger 140 a coupled with a cooling water source 142 a prior to entering the anode compartment 108 of the electrolyzer 102 .
  • the cathode compartment 110 generally includes a cathode feed stream 144 that includes carbon dioxide and a catholyte.
  • the catholyte is a bicarbonate compound, such as potassium bicarbonate (KHCO 3 ), which is saturated with carbon dioxide.
  • the cathode feed stream 144 may enter a bottom of the cathode compartment 110 to flow by a face of the cathode 118 and through the high surface area cathode structure 120 .
  • the reaction in the cathode compartment 110 may reduce carbon dioxide to formate at an applied current and voltage potential.
  • the reaction products and any unreacted materials (e.g., excess catholyte solution) may exit the cathode compartment 110 as cathode exit stream 146 .
  • the cathode exit stream 146 may be monitored by a pH sensor 148 a and a temperature sensor 126 b and may flow to a catholyte disengager 150 suitable for separating gaseous components (e.g., hydrogen) from the cathode exit stream 146 .
  • the catholyte disengager 150 may process the cathode exit stream 146 into a hydrogen stream 152 , a product stream 154 , and a catholyte recycle stream 156 .
  • the hydrogen stream 152 may be vented from the catholyte disengager 150 .
  • the product stream 154 preferably includes an alkali metal formate (such as potassium formate where the electrolyte includes potassium bicarbonate) and may include excess catholyte.
  • the catholyte stream 156 may be processed by a catholyte recirculation pump 158 and a heat exchanger 140 b coupled with a cooling water source 142 b .
  • a temperature sensor 126 c may monitor the catholyte stream 156 downstream from the heat exchanger 140 b having cooling water source 142 b .
  • a fresh catholyte electrolyte feed 160 may be metered into the catholyte stream 156 , where the fresh catholyte electrolyte feed 160 may adjust the pH of the cathode feed stream 144 into the cathode compartment 110 of the electrolyzer 102 , which may control final product overflow rate and establish the formate product concentration.
  • the pH may be monitored by pH sensor 148 b .
  • a carbon dioxide stream 162 may be metered into the cathode feed stream 144 downstream from the catholyte electrolyte feed 160 prior to entering the cathode compartment 110 of the electrolyzer 102 .
  • the carbon dioxide saturates the catholyte entering the cathode compartment.
  • the pH of the electrolyzer 102 may be controlled or maintained through use of an alkali metal bicarbonate and/or carbonate in combination with water to control the pH of the catholyte.
  • the cell may more efficiently convert carbon dioxide into C1 and C2 products with a higher conversion rate than if a non-optimum pH value was maintained or if no pH control mechanism was employed.
  • the catholyte is constantly recirculated to maintain an adequate and uniform carbon dioxide concentration at cathode surfaces coated with an electrocatalyst.
  • a fresh catholyte feed stream may be used to control the pH of the catholyte and to control the product concentration in the product overflow stream.
  • the mass flow rate of the catholyte feed to the cathode compartment e.g., mass flow of potassium bicarbonate
  • the concentration of the potassium bicarbonate is important, since it provides volume to the catholyte, which will dilute the product in the catholyte.
  • potassium bicarbonate is preferred, in a concentration range of 5 to 600 gm/L, or more preferably in the 10 to 500 gm/L range. If the feed concentration of bicarbonate to the catholyte is fixed, a separate feed of water may be employed into the catholyte to control final product concentration. In another implementation, potassium carbonate may be used as a feed for pH control. Potassium carbonate has a much higher solubility in water than potassium bicarbonate, and is preferably used in a concentration range of 5 to 1,500 gm/L.
  • the electrochemical acidification system 200 may be utilized to acidify the product stream 154 from the electrolyzer system 100 .
  • the electrochemical acidification system 200 acidifies an alkali metal formate, such as potassium formate, to form an organic acid, such as formic acid, and co-produce an alkali metal hydroxide, such as potassium hydroxide.
  • the electrochemical acidification system 200 generally includes an electrochemical acidification unit 202 , an anolyte recycle loop 204 , and a catholyte recycle loop 206 .
  • the electrochemical acidification system 200 may include as process feeds/inputs the product stream 154 from the electrolyzer system 100 (which preferably includes an alkali metal formate), water in each of the anolyte recycle loop 204 and the catholyte recycle loop 206 , and an acidic anolyte (preferably sulfuric acid, but may include other acids, instead of, or in addition to sulfuric acid).
  • the product of the electrochemical acidification system 200 is generally an organic acid, such as formic acid, and an alkali metal hydroxide, and may include residual alkali metal formate, bicarbonate catholyte, carbon dioxide, hydrogen, oxygen, and/or other unreacted process inputs.
  • the electrochemical acidification unit 202 is preferably a three-compartment electrochemical acidification unit or cell.
  • the electrochemical acidification unit 202 generally includes an anode compartment 208 , a cathode compartment 210 , and a central ion exchange compartment 212 bounded by cation exchange membranes 214 a and 214 b on each side.
  • the anode compartment 208 includes an anode 216 suitable to oxidize water.
  • the anode 216 is a titanium anode having an anode electrocatalyst coating which faces the cation exchange membrane 214 a .
  • the cathode compartment 210 includes a cathode 218 suitable to reduce water and to generate an alkali metal hydroxide.
  • hydrogen ions (H + ) or protons are generated in the anode compartment 208 when a potential and current are applied to the electrochemical acidification unit 202 .
  • the hydrogen ions (H + ) or protons pass through the cation exchange membrane 214 a into the central ion exchange compartment 212 .
  • the product stream 154 from the electrolyzer system 100 is preferably introduced to the electrochemical acidification unit 202 via the central ion exchange compartment 212 , where the hydrogen ions (H + ) or protons displace the alkali metal ions (e.g., potassium ions) in the product stream 154 to acidify the stream and produce a product stream 260 including an organic acid product, preferably formic acid.
  • alkali metal ions e.g., potassium ions
  • the displaced alkali metal ions may pass through the cation exchange membrane 214 b to the cathode compartment 210 to combine with hydroxide ions (OH ⁇ ) formed from water reduction at the cathode 218 to form an alkali metal hydroxide, preferably potassium hydroxide.
  • hydroxide ions OH ⁇
  • the central ion exchange compartment 212 may include a plastic mesh spacer (not shown) to maintain the dimensional space in the central ion exchange compartment 212 between the cation exchange membranes 214 a and 214 b .
  • a cation ion exchange material 220 is included in the central ion exchange compartment 212 between the cation exchange membranes 214 a and 214 b .
  • the cation ion exchange material 220 may include an ion exchange resin in the form of beads, fibers, and the like.
  • the cation ion exchange material 220 may increase electrolyte conductivity in the ion exchange compartment solution, and may reduce the potential effects of carbon dioxide gas on the cell voltage as bubbles are formed and pass through the central ion exchange compartment 212 .
  • the anode compartment 208 generally includes an anode feed stream 222 that includes an acid anolyte solution (preferably a sulfuric acid solution).
  • the gaseous oxygen and other liquids leaving the anode compartment 208 of the electrochemical acidification unit 202 leave as anode exit stream 224 .
  • the anode exit stream 224 may be monitored by a temperature sensor 226 a and may flow to an anolyte disengager 228 suitable for separating the oxygen from the anode exit stream 224 .
  • the anolyte disengager 228 may process the anode exit stream 224 into an oxygen stream 230 , an anolyte recycle stream 232 , and an anolyte overflow stream 234 .
  • the oxygen stream 230 may be vented from the anolyte disengager 228 .
  • the anolyte stream 232 may be combined with water (preferably deionized water) from a water source 236 and with acid (preferably sulfuric acid) from an acid source 238 .
  • the water source 236 and the acid source 238 in the anolyte recycle loop 204 may maintain anolyte acid strength and volume for the anode feed stream 222 .
  • the temperature of the anode feed stream 222 may be regulated by a heat exchanger 240 a coupled with a cooling water source 242 a prior to entering the anode compartment 208 of the electrochemical acidification unit 202 .
  • the cathode compartment 210 generally includes a catholyte feed stream 244 that includes water and may include an alkali metal hydroxide that circulates through the catholyte recycle loop 206 .
  • the reaction products which may include the alkali metal hydroxide and hydrogen gas, may exit the cathode compartment 210 as cathode exit stream 246 .
  • the cathode exit stream 246 may be monitored by a temperature sensor 226 b and may flow to a catholyte disengager 248 suitable for separating gaseous components (e.g., hydrogen) from the cathode exit stream 246 .
  • the catholyte disengager 248 may process the cathode exit stream 246 into a hydrogen stream 250 , a catholyte stream 252 , and a catholyte overflow stream 254 , which may include KOH.
  • the hydrogen stream 250 may be vented from the catholyte disengager 248 .
  • the catholyte stream 252 preferably includes an alkali metal hydroxide (such as potassium hydroxide where the product steam 154 includes potassium formate).
  • the catholyte stream 252 may be processed by a catholyte recirculation pump 256 and a heat exchanger 240 b coupled with a cooling water source 242 b .
  • a temperature sensor 226 c may monitor the catholyte stream 252 downstream from the heat exchanger 240 b .
  • the catholyte stream 252 may be combined with water (preferably deionized water) from a water source 258 , where the water may be metered to control the concentration of the alkali metal hydroxide in the catholyte feed stream 244 entering the cathode compartment 210 .
  • the system 300 may incorporate the electrolyzer system 100 (described with reference to FIG. 1 ) and the electrochemical acidification system 200 (described with reference to FIG. 2 ), and preferably includes a potassium hydroxide recycle loop 302 suitable for the production of potassium bicarbonate from potassium hydroxide and carbon dioxide.
  • the system 300 may also incorporate carbon dioxide processing components for the separation (e.g., gas separation units 304 a , 304 b , 304 c , 304 d ) and recovery of carbon dioxide from process streams.
  • the system 300 generally includes carbon dioxide, an alkali metal hydroxide (preferably potassium hydroxide), an acid (preferably sulfuric acid), and water (preferably deionized water) as process inputs and generally includes an organic acid (preferably formic acid), oxygen gas, and hydrogen gas as process outputs.
  • the organic acid may undergo additional processing to provide a desired form and concentration. Such processing may include evaporation, distillation, or another suitable physical separation/concentration process.
  • the chemistry of the reduction of carbon dioxide in the system 300 may be as follows.
  • Hydrogen atoms are adsorbed at the electrode from the reduction of water as shown in equation (1).
  • Carbon dioxide is reduced at the cathode surface with the adsorbed hydrogen atom to form formate, which is adsorbed on the surface as in equation (2).
  • the competing reaction at the cathode is the reduction of water where hydrogen gas is formed as well as hydroxide ions as in equation (4).
  • the anode reaction is the oxidation of water into oxygen and hydrogen ions as shown in equation (5).
  • the cathode 118 preferably includes a high surface area cathode structure 120 .
  • the high surface area cathode structure 120 preferably includes a void volume ranging from 30% to 98%.
  • the specific surface area of the high surface area cathode structure 120 is preferably from 2 cm 2 /cm 3 to 500 cm 2 /cm 3 or higher.
  • the surface area also can be defined as total area in comparison to the current distributor/conductor back plate, with a preferred range of 2 ⁇ to 1000 ⁇ or more.
  • the cathode 118 preferably includes electroless indium on tin (Sn) coated copper woven mesh, copper screen, copper fiber as well as bronze and other are copper-tin alloys, nickel and stainless steels.
  • the metals may be precoated with other metals, such as to adequately form a suitable base for the application of the indium and other preferred cathode coatings.
  • the cathode may also include Indium-Cu intermetallics formed on the surfaces of copper fiber, woven mesh, copper foam or copper screen.
  • the intermetallics are generally harder than the soft indium metal, and may provide desirable mechanical properties in addition to usable catalytic properties.
  • the cathode may also include, but is not limited to coatings and/or metal structures containing Pb, Sn, Hg, Tl, In, Bi, and Cd, their alloys, and combinations thereof. Metals including Ti, Nb, Cr, Mo, Ag, Cd, Hg, Tl, An, and Pb as well as Cr—Ni—Mo steel alloys among many others may be incorporated.
  • the cathode 118 may include a single or multi-layered electrode coating, such that the electrocatalyst coating on the cathode substrate includes one or more layers of metals and alloys.
  • a preferred electrocatalyst coating on the cathode includes a tin coating on a high surface area copper substrate with a top layer/coating of indium. The indium coating coverage preferably ranges from 5% to 100% as indium.
  • the indium composition preferably ranges from 5% to 99% as indium in alloys with other metals, including Sn, Pb, Hg, Tl, Bi, Cu, and Cd and their mixed alloys and combinations thereof. It is also contemplated to include Au, Ag, Zn, and Pd into the coating in percentages ranging from 1% to 95%.
  • metal oxides may be used or prepared as electrocatalysts on the surfaces of the base cathode structure.
  • lead oxide can be prepared as an electrocatalyst on the surfaces of the base cathode structure.
  • the metal oxide coating could be formed by a thermal oxidation method or by electro-deposition followed by chemical or thermal oxidation.
  • the cathode base structure can also be gradated or graduated, such that the density of the cathode can be varied in the vertical or horizontal directions in terms of density, void volume, or specific surface area (e.g., varying fiber sizes).
  • the cathode structure may also consist of two or more different electrocatalyst compositions that are either mixed or located in separate regions of the cathode structure in the catholyte compartment.
  • the performance of the system may decrease with regard to formate yield which may result from catalyst loss or over-coating of the catalyst with impurities, such as other metals that may be plated onto the cathode 118 .
  • the surfaces of the cathode 118 may be renewed by the periodic addition of indium salts or a mix of indium/tin salts in situ during operation of the electrolyzer 102 .
  • other or additional metal salts may be added in situ including salts of Ag, Au, Mo, Cd, Sn, and other suitable metals, singly or in combination.
  • the electrolyzer 102 may be operated at full rate during operation, or temporarily operated at a lower current density with or without any carbon dioxide addition during the injection of the metal salts.
  • the conditions under which to renew the cathode surface with the addition of these salts may differ depending on desired renewal results.
  • the use of an occasional brief current reversal during electrochemical cell operation may also be employed to potentially renew the cathode surfaces.
  • the electrolyzer 102 is operated at pressures exceeding atmospheric pressure, which may result in higher current efficiency and permit operation of the electrolyzer 102 at higher current densities than when operating the electrolyzer 102 at or below atmospheric pressure.
  • metal salts that can reduce on the surfaces of the cathode structure can be also used, such as the addition of Ag, Au, Mo, Cd, Sn, and other suitable metals.
  • Such addition of metal salts may provide a catalytic surface that may be otherwise difficult to prepare directly during cathode fabrication or for renewal of the catalytic surfaces.
  • a preferred method for preparing the high surface area cathode structure 120 is using an electroless plating solution which may include an indium salt, at least one complexing agent, a reducing agent, a pH modifier, and a surfactant.
  • the preferred procedure for forming an electroless indium coating on the high surface area cathode may include combining in stirred deionized water the following materials: Trisodium citrate dihydrate (100 g/L), EDTA-disodium salt (15 g/L), sodium acetate (10 g/L), InCl 3 (anhydrous, 10 g/L), and Thiodiglycolic acid (0.3 g/L, e.g., 3 mL of 100 mg/mL solution).
  • a pre-mixed stock deposition solution that has been stirred may also be used.
  • the procedure also includes heating the mixture to about 40° C.
  • the procedure also includes adding 40 mL TiCl 3 (20 wt. % in 2% HCl) per liter [0.05 mM] and adding 7M ammonia in methanol until the pH of the mixture is approximately 7 ( ⁇ 15 mL ammonia solution per liter) at which point ammonium hydroxide (28% ammonia solution) is used to adjust the pH to between approximately 9.0 and 9.2.
  • the procedure then includes heating the mixture to about 60° C. If the pH drops, adjust the pH to approximately 9.0 with ammonium hydroxide solution.
  • the procedure then includes heating the mixture to about 75° C., where deposition may begin at about 65° C.
  • the procedure includes holding the mixture at 75° C. for about one hour.
  • a preferred procedure for the metallic coating of copper substrates may include rinsing bare copper substrates in acetone to clean the copper surface (e.g., removing residual oils or grease that may be present on the copper surface) and then rinsing the acetone-treated copper substrates in deionized water.
  • the procedure also includes immersing the bare copper substrates in a 10% sulfuric acid bath for approximately 5 minutes, and then rinsing with deionized water.
  • the procedure also includes depositing approximately 25 ⁇ m of tin on the copper surface. The deposition may be done using a commercial electroless tinning bath (Caswell, Inc.) operated at 60° C. for 15 minutes. Following tin deposition, parts are rinsed thoroughly in deionized water.
  • the procedure also includes depositing approximately 1 ⁇ m of indium on the tinned copper surface.
  • the deposition may be done using an electroless bath operated at 90° C. for 60 minutes. Following indium deposition, parts are rinsed thoroughly in deionized water.
  • the procedure may also include treated the copper/tin/indium electrode in a 5 wt % nitric acid bath for 5 minutes. Such treatment may improve electrode stability as compared to an untreated copper/tin/indium electrode.
  • the electroless tin plated copper substrate may be dipped into molten indium for coating.
  • cathode substrates may be treated with catalytic materials for carbon dioxide reduction.
  • catalytic materials for carbon dioxide reduction Four example treatments are presented by the following.
  • a first treatment may include coating a conductive substrate (e.g., vitreous carbon or metal) in a conductive sol-gel containing sufficient catalyst material to yield a high active surface area.
  • the conductive component of the sol-gel may be catalytically active.
  • the sol-gel is allowed to undergo a high degree of polymerization/cross-linking.
  • the combined substrate/sol-gel structure may then be pyrolized at high temperature to convert organic material to amorphous (and potentially conductive) carbon.
  • the pyrolized structure may also be subjected to chemical treatments that selectively remove the organic material or the silica phase, leading to a high catalyst content coating.
  • the second treatment may include binding relatively small particles (e.g., micron or nanometer scale) to a substrate using a binding agent such as amines, thiols, or other suitable binding agent.
  • the binding agent is preferably conductive to pass current between the substrate and catalyst particles.
  • the catalyst particles preferably include conjugated organic molecules, such as diphenybenzene. If the substrate is also made of catalyst material the binding agent may have symmetrical binding groups, otherwise binding agents with two different binding groups may be utilized.
  • the third treatment may include coating a substrate in a slurry containing catalyst material (which may be in salt form) and a binding agent.
  • the slurry may also contain a conductive additive, such as carbon black, carbon nanotubes, or other suitable conductive additive.
  • the slurry coating may then be dried to form a conformal coating over the substrate.
  • the substrate and dried slurry coating may be heated in order to fuse the various constituent materials into a mechanically robust, conductive, and catalytic material. In a particular implementation, the heating of the substrate and dried slurry coating occurs in a reducing environment.
  • the fourth treatment may include coating a substrate with semiconducting metal chalcogenides by applying a precursor to the substrate, removing solvent, and baking the substrate to convert the precursor material to a monolithic semiconducting metal chalcogenide coating.
  • the coating materials may include, but are not limited to, Na 4 SnS 4 , Na 4 Sn 2 S 6 , K 4 SnTe 4 , Na 3 AsS 3 , (NH 4 ) 4 Sn 2 S 6 , (NH 4 ) 3 AsS 3 , and (NH 4 ) 2 MoS 4 .
  • thermal oxides onto a substrate forming an intermetallic with a substrate, and applying semiconductor materials on a substrate.
  • thermal oxidation of various metal salts painted onto various metal and ceramic substrates is preferred for forming high surface area materials suitable for the electrochemical reduction of carbon dioxide.
  • the thermal oxidation may be similar to that used for forming electrocatalysts on titanium for use as anode materials in electrochemical chlorine cells, such as iridium oxide and ruthenium oxide.
  • indium is electroplated onto a copper foil, then the copper foil is heated to 40° C.
  • the formation of the intermetallic can be done in air or under an inert gas atmosphere (e.g., argon or helium) or under a full or partial vacuum.
  • the electroplated material preferably provides approximately 50% Faradaic conversion efficiency, and may be utilized as a coating on planar metal back plates and also on copper fibers.
  • An intermetallic may also be formed with tin-plated copper substrates.
  • a semiconductor material may be applied to a substrate by gaseous deposition, sputtering, or other suitable application methods.
  • the substrate is preferably a metallic substrate.
  • the semiconductor materials may be doped to P-type or N-type as desired.
  • certain measures may be taken to improve the quality (mechanical, electrical, etc.) of the bond between the substrate and catalyst.
  • measures may involve creating functional groups on the substrate surface that can undergo chemical bonding with the catalyst or a binding agent, or the creation of geometrical features in the substrate surface that facilitate bonding with an applied catalyst coating.
  • the substrate for the high surface area cathodes described herein may include RVC materials, such as carbon and graphite, metal foams, woven metals, metal wools made from fibers, sintered powder metal films and plates, metal and ceramic beads, pellets, ceramic and metal column and trickle bed packing materials, metal and inorganic powder forms, metal fibers and wools, or other suitable substrate materials.
  • RVC materials such as carbon and graphite, metal foams, woven metals, metal wools made from fibers, sintered powder metal films and plates, metal and ceramic beads, pellets, ceramic and metal column and trickle bed packing materials, metal and inorganic powder forms, metal fibers and wools, or other suitable substrate materials.
  • the specific surface area of the physical forms preferably include a specific surface area between approximately 2 and 2,000 cm 2 /cm 3 or greater.
  • the electrode or high surface area structure of an electrode may incorporate alloys as fibers or wools, and may be coated with various compounds, and subsequently fired in air or in a reducing atmosphere oven, to form stable oxides on the surfaces which are electrocatalytic in the reduction of carbon dioxide.
  • Other cathode materials may include metallic glasses and amorphous metals.
  • the alkali metal formate e.g., potassium formate
  • the alkali metal formate may be acidified in addition to recovering potassium hydroxide.
  • the use of the bipolar membranes may reduce the voltage required for the acidification of the alkali metal formate and may reduce the number of actual anodes and cathodes needed for the electrochemical stack.
  • the bipolar membranes preferably consist of a cation membrane and an anion membrane that have been bonded together, and function by splitting water at the two membrane interface, forming hydrogen (H + ) ions from the cation membrane and hydroxide ions (OH ⁇ ) from the anion membrane.
  • the electrolyzer 502 in FIG. 5 includes an ion exchange compartment 504 in addition to an anode 506 compartment and a cathode compartment 508 .
  • This ion exchange compartment 504 functions similarly as the acid acidification compartment 212 in electrochemical acidification unit 202 as shown in FIG. 2 .
  • the alkali metal formate product e.g., potassium formate
  • unreacted KHCO 3 from the cathode compartment is passed through the ion exchange compartment 504 to provide a formic acid product with CO 2 and some residual KHCO 3 .
  • the hydrogen ions (H + ) passing through the adjacent membrane 510 a on the anode compartment side displace the alkali metal ions (e.g., K + ) in the stream passing through the central ion exchange compartment 504 so that the alkali metal formate is acidified and the alkali metal ions and remaining hydrogen ions pass through the adjoining membrane 510 b on the cathode compartment 508 and into the catholyte.
  • This will allow operation of the catholyte at higher pH conditions if required for obtaining high Faradaic current efficiencies with the cathodes selected for the process.
  • the preferred catholytes include alkali metal bicarbonates, carbonates, sulfates, phosphates, and the like.
  • Other preferred catholytes include borates, ammonium, and hydroxides.
  • Other catholytes may include chlorides, bromides, and other organic and inorganic salts.
  • Non-aqueous electrolytes such as propylene carbonate, methanesulfonic acid, methanol, and other ionic conducting liquids may be used, which may be in an aqueous mixture, or as a non-aqueous mixture in the catholyte. The introduction of micro bubbles of carbon dioxide into the catholyte stream may improve carbon dioxide transfer to the cathode surfaces.
  • a nano-filtration system may be utilized between the electrolyzer system 100 , as shown in FIG. 1 , and the electrochemical acidification system 200 , as shown in FIG. 2 .
  • the nano-filtration system is preferably utilized to separate alkali metal formate (e.g., potassium formate) from bicarbonate leaving the electrolyzer system 100 (e.g., stream 154 ) to reduce the amount of bicarbonate entering the electrochemical acidification unit 202 .
  • the nano-filtration system preferably uses a nano-filtration filter/membrane under pressure for selective separation of the bicarbonate from the alkali metal formate.
  • the nano-filtration filter/membrane separates monovalent anions (e.g., formate) from divalent anions (e.g., carbonate) using a high pressure pump and suitable selected membranes for the separation.
  • monovalent anions e.g., formate
  • divalent anions e.g., carbonate
  • the bicarbonate in the formate/bicarbonate product e.g., stream 154
  • the nano-filtration system may include a mixer, such as a mixing tank, to mix the formate/bicarbonate product stream with a potassium hydroxide (KOH) stream.
  • KOH potassium hydroxide
  • the mixer may promote the conversion of potassium bicarbonate to potassium carbonate to facilitate the separation of the formate from the carbonate.
  • a high pressure pump then sends the potassium formate/carbonate stream into a nano-filtration unit which includes the nano-filtration filter/membrane.
  • the nano-filtration unit produces a low-carbonate-containing potassium formate permeate stream which is then sent to the electrochemical acidification system 200 as shown in FIG. 2 as stream 154 , to enter the electrochemical acidification unit 202 .
  • the potassium carbonate containing reject stream leaving the nano-filtration unit is preferably sent to the KHCO 3 block of FIG. 3 , where the potassium carbonate is mixed with KOH and CO 2 for conversion to potassium bicarbonate.
  • the potassium bicarbonate is preferably utilized as a feed to the cathode compartment of the electrolyzer 102 of the electrolyzer system 100 .
  • the nano-filtration separation system may consist of multiple units connected in a series flow configuration to increase the total separation efficiency of the carbonate from formate separation.
  • the system may also utilize recycle streams to recycle an output stream from one unit to the input of another unit to maintain flow and pressures as well as to increase the recovery of the formate.
  • the pH of the catholyte preferably ranges from 3 to 12.
  • the desired pH of the catholyte may be a function of the catholyte operating conditions and the catalysts used in the cathode compartment, such that there is limited or no corrosion at the electrochemical cell.
  • Preferable catholyte cross sectional area flow rates may include a range of 2 to 3,000 gpm/ft 2 or more (0.0076 to 11.36 m 3 /m 2 ), with a flow velocity range of 0.002 to 20 ft/sec (0.0006 to 6.1 m/sec).
  • a homogenous heterocyclic catalyst is preferably utilized in the catholyte.
  • the homogenous heterocyclic catalyst may include, for example, one or more of 4-hydroxy pyridine, adenine, a heterocyclic amine containing sulfur, a heterocyclic amine containing oxygen, an azole, a benzimidazole, a bipyridine, furan, an imidazole, an imidazole related species with at least one five-member ring, an indole, a lutidine, methylimidazole, an oxazole, phenanthroline, pterin, pteridine, a pyridine, a pyridine related species with at least one six-member ring, pyrrole, quinoline, or a thiazole, and mixtures thereof.
  • Preferred anolytes for the system include alkali metal hydroxides, such as KOH, NaOH, LiOH; ammonium hydroxide; inorganic acids such as sulfuric, phosphoric, and the like; organic acids such as methanesulfonic acid; non-aqueous and aqueous solutions; alkali halide salts, such as the chlorides, bromides, and iodine types such as NaCl, NaBr, LiBr, and NaI; and acid halides such as HCl, HBr and Hl.
  • alkali metal hydroxides such as KOH, NaOH, LiOH
  • ammonium hydroxide such as sulfuric, phosphoric, and the like
  • organic acids such as methanesulfonic acid
  • non-aqueous and aqueous solutions alkali halide salts, such as the chlorides, bromides, and iodine types such as NaCl, NaBr, LiBr, and NaI
  • the acid halides and alkali halide salts will produce for example chlorine, bromine, or iodine as a halide gas or as dissolved aqueous products from the anolyte compartment.
  • Methanol or other hydrocarbon non-aqueous liquids can also be used, and would form some oxidized organic products from the anolyte.
  • Selection of the anolyte would be determined by the process chemistry product and requirements for lowering the overall operating cell voltage. For example, the formation of bromine at the anode requires a significantly lower anode voltage potential than chlorine formation, and iodine is even lower than that of bromine. This allows for a significant power cost savings in the operation of both of the electrochemical units when bromine is generated in the anolyte.
  • a halogen such as bromine
  • anolyte may then be used in an external reaction to produce other compounds, such as reactions with alkanes to form bromoethane, which may then be converted to an alcohol, such as ethanol, or an alkene, such as ethylene, and the halogen acid byproduct from the reaction can be recycled back to the electrochemical cell anolyte.
  • a halogen such as bromine
  • Electrochemical cells may operate at pressures up to about 20 to 30 psig in multi-cell stack designs, although with modifications, they could operate at up to 100 psig.
  • the electrolyzer anolyte may also be operated in the same pressure range to minimize the pressure differential on the membrane separating the two electrode compartments.
  • Special electrochemical designs are required to operate electrochemical units at higher operating pressures up to about 60 to 100 atmospheres or greater, which is in the liquid CO 2 and supercritical CO 2 operating range.
  • a portion of the catholyte recycle stream may be separately pressurized using a flow restriction with backpressure or using a pump, with CO 2 injection, such that the pressurized stream is then injected into the catholyte compartment of the electrolyzer.
  • Such a configuration may increase the amount of dissolved CO 2 in the aqueous solution to improve the conversion yield.
  • Catholyte and anolyte operating temperatures preferably range from ⁇ 10 to 95° C., more preferably 5 to 60° C.
  • the minimum operating temperature will be limited to the electrolytes used and their freezing points. In general, the lower the temperature, the higher the solubility of CO 2 in the aqueous solution phase of the electrolyte, and would help in obtaining higher conversion and current efficiencies.
  • a consideration for lower operating temperatures is that the operating electrolyzer cell voltages may be higher, so an optimization may be required to produce the chemicals at the lowest operating cost.
  • the electrochemical cell design may include a zero gap, flow-through design with a recirculating catholyte electrolyte with various high surface area cathode materials.
  • Other designs include: flooded co-current packed and trickle bed designs with the various high surface area cathode materials, bipolar stack cell designs, and high pressure cell designs.
  • Anodes for use in the electrochemical system may depend on various system conditions.
  • the anode may include a coating, with preferred electrocatalytic coatings including precious metal oxides, such as ruthenium and iridium oxides, as well as platinum, rhodium, and gold and their combinations as metals and oxides deposited on valve metal substrates, such as titanium, tantalum, zirconium, and niobium.
  • precious metal oxides such as ruthenium and iridium oxides, as well as platinum, rhodium, and gold and their combinations as metals and oxides deposited on valve metal substrates, such as titanium, tantalum, zirconium, and niobium.
  • the anode made include carbon, cobalt oxides, stainless steels, nickel, and their alloys and combinations which may be stable as anodes suitable under alkaline conditions.
  • the electrochemical system may employ a membrane positioned between the anode compartment and the cathode compartment.
  • Cation ion exchange type membranes are preferred, especially those that have a high rejection efficiency to anions, for example perfluorinated sulfonic acid based ion exchange membranes such as DuPont Nafion® brand unreinforced types N117 and N120 series, more preferred PTFE fiber reinforced N324 and N424 types, and similar related membranes manufactured by Japanese companies under the supplier trade names such as Flemion®.
  • multi-layer perfluorinated ion exchange membranes used in the chlor alkali industry have a bilayer construction of a sulfonic acid based membrane layer bonded to a carboxylic acid based membrane layer, which efficiently operates with an anolyte and catholyte above a pH of about 2 or higher. These membranes have a much higher anion rejection efficiency. These are sold by DuPont under their Nafion® trademark as the N900 series, such as the N90209, N966, N982, and the 2000 series, such as the N2010, N2020, and N2030 and all of their types and subtypes.
  • Hydrocarbon based membranes which are made from various cation ion exchange materials can also be used if the anion rejection is not as critical, such as those sold by Sybron under their trade name Ionac®, AGC Engineering (Asahi Glass) under their Selemion® trade name, and Tokuyama Soda, among others available on the market.
  • the electrolyzer design used in laboratory examples may incorporate various thickness high surface area cathode structures using added spacer frames and also provide the physical contact pressure for the electrical contact to the cathode current conductor backplate.
  • An electrochemical bench scale cell with an electrode projected area of about 108 cm 2 was used for much of the bench scale test examples.
  • the electrochemical cell was constructed consisting of two electrode compartments machined from 1.0 inch (2.54 cm) thick natural polypropylene.
  • the outside dimensions of the anode and cathode compartments were 8 inches (20.32 cm) by 5 inches (12.70 cm) with an internal machined recess of 0.375 inches (0.9525 cm) deep and 3.0 inches (7.62 cm) wide by 6 inches (15.24 cm) tall with a flat gasket sealing area face being 1.0 inches (2.52 cm) wide.
  • Two holes were drilled equispaced in the recess area to accept two electrode conductor posts that pass though the compartment thickness, and having two 0.25 inch (0.635 cm) drilled and tapped holes to accept a plastic fitting that passes through 0.25 inch (0.635 cm) conductor posts and seals around it to not allow liquids from the electrode compartment to escape to the outside.
  • the electrode frames were drilled with an upper and lower flow distribution hole with 0.25 inch pipe threaded holes with plastic fittings installed to the outside of the cell frames at the top and bottom of the cells to provide flow into and out of the cell frame, and twelve 0.125 inch (0.3175 cm) holes were drilled through a 45 degree bevel at the edge of the recess area to the upper and lower flow distribution holes to provide an equal flow distribution across the surface of the flat electrodes and through the thickness of the high surface area electrodes of the compartments.
  • an anode with a thickness of 0.060 inch (0.1524 cm) and 2.875 inch (7.3025 cm) width and 5.875 inch (14.9225 cm) length with two 0.25 inch (0.635 cm) titanium diameter conductor posts welded on the backside were fitted through the two holes drilled in the electrode compartment recess area.
  • the positioning depth of the anode in the recess depth was adjusted by adding plastic spacers behind the anode, and the edges of the anode to the cell frame recess were sealed using a medical grade epoxy.
  • the electrocatalyst coating on the anode was a Water Star WS-32, an iridium oxide based coating on a 0.060 inch (0.1524 cm) thick titanium substrate, suitable for oxygen evolution in acids.
  • the anode compartment also employed an anode folded screen (folded three times) that was placed between the anode and the membrane, which was a 0.010 inch (0.0254 cm) thick titanium expanded metal material from DeNora North America (EC626), with an iridium oxide based oxygen evolution coating, and used to provide a zero gap anode configuration (anode in contact with membrane), and to provide pressure against the membrane from the anode side which also had contact pressure from the cathode side.
  • 316L stainless steel cathodes with a thickness of 0.080 inch (0.2032 cm) and 2.875 inch (7.3025 cm) width and 5.875 inch (14.9225 cm) length with two 0.25 inch (0.635 cm) diameter 316L SS conductor posts welded on the backside were fitted through the two holes drilled in the electrode compartment recess area.
  • the positioning depth of the cathode in the recess depth was adjusted by adding plastic spacers behind the cathode, and the edges of the cathode to the cell frame recess were sealed using a fast cure medical grade epoxy.
  • a copper bar was connected between the two anode posts and the cathode posts to distribute the current to the electrode back plate.
  • the cell was assembled and compressed using 0.25 inch (0.635 cm) bolts and nuts with a compression force of about 60 in-lbs force.
  • Neoprene elastomer is gaskets (0.0625 inch (0.159 cm) thick) were used as the sealing gaskets between the cell frames, frame spacers, and the membranes.
  • the above cell was assembled with a 0.010 inch (0.0254 cm) thickness indium foil mounted on the 316L SS back conductor plate using a conductive silver epoxy.
  • a multi-layered high surface area cathode comprising an electrolessly applied indium layer of about 1 micron thickness that was deposited on a previously applied layer of electroless tin with a thickness of about 25 micron thickness onto a woven copper fiber substrate.
  • the base copper fiber structure was a copper woven mesh obtained from an on-line internet supplier, PestMall.com (Anteater Pest Control Inc.).
  • the copper fiber dimensions in the woven mesh had a thickness of 0.0025 inches (0.00635 cm) and width of 0.010 inches (0.0254 cm).
  • the prepared high surface area cathode material was folded into a pad that was 1.25 inches (3.175 cm) thick and 6 inches (15.24 cm) high and 3 inches (7.62 cm) wide, which filled the cathode compartment dimensions and exceeded the adjusted compartment thickness (adding spacer) which was 0.875 inches (2.225 cm) by about 0.25 inches (0.635 cm).
  • the prepared cathode had a calculated surface area of about 3,171 cm 2 , for an area about 31 times the flat cathode plate area, with a 91% void volume, and specific surface area of 12.3 cm 2 /cm 3 .
  • the cathode pad was compressible, and provided the spring force to make contact with the cathode plate and the membrane.
  • Neoprene gaskets (0.0625 inch (0.159 cm) thick) were used as the sealing gaskets between the cell frames and the membranes.
  • the electrocatalyst coating on the anode in the anolyte compartment was a Water Star WS-32, an iridium oxide based coating, suitable for oxygen evolution in acids.
  • the anode compartment also employed a three-folded screen that was placed between the anode and the membrane, which was a 0.010 inch (0.0254 cm) thick titanium expanded metal material from DeNora North America (EC626), with an iridium oxide based oxygen evolution coating, and used to provide a zero gap anode configuration (anode in contact with membrane), and to provide pressure against the membrane from the anode side which also had contact pressure from the cathode side.
  • EC626 DeNora North America
  • the cell assembly was tightened down with stainless steel bolts, and mounted into the cell station, which has the same configuration as shown in FIG. 1 with a catholyte disengager, a centrifugal catholyte circulation pump, inlet cell pH and outlet cell pH sensors, a temperature sensor on the outlet solution stream.
  • a 5 micron stainless steel frit filter was used to sparge carbon dioxide into the solution into the catholyte disengager volume to provide dissolved carbon dioxide into the recirculation stream back to the catholyte cell inlet.
  • the anolyte used was a dilute 5% by volume sulfuric acid solution, made from reagent grade 98% sulfuric acid and deionized water.
  • Catholyte flow rate 2.5 LPM
  • Catholyte flow velocity 0.08 ft/sec
  • Applied cell current 6 amps (6,000 mA)
  • Catholyte pH range 5.5-6.6, controlled by periodic additions of potassium bicarbonate to the catholyte solution recirculation loop.
  • Catholyte pH declines with time, and is controlled by the addition of potassium bicarbonate.
  • Example 1 The same cell as in Example 1 was used with the same cathode, which was only rinsed with water while in the electrochemical cell after the run was completed and then used for this run.
  • Catholyte Solution 0.4 M K 2 SO 4 , 0.4 M KHCO 3
  • Catholyte flow rate 2.5 LPM
  • Catholyte flow velocity 0.08 ft/sec
  • Applied cell current 6 amps (6,000 mA)
  • Catholyte pH range Dropping from 7.5 to 6.75 linearly with time during the run.
  • Catholyte Solution 0.2 M K 2 SO 4 , 0.4 M KHCO 3
  • Catholyte flow rate 2.5 LPM
  • Catholyte flow velocity 0.08 ft/sec
  • Applied cell current 9 amps (9,000 mA)
  • Catholyte pH range Dropping from 7.5 to 6.65 linearly with time during the run, and then additional solid KHCO 3 was added to the catholyte loop in 10 gm increments at the 210, 252, and 290 minute time marks which brought the pH back up to about a pH of 7 for the last part of the run.
  • Catholyte flow rate 2.6 LPM
  • Catholyte flow velocity 0.09 ft/sec
  • Applied cell current 11 amps (11,000 mA)
  • Catholyte pH range Dropping from around 7.8 linearly with time during the run to a final pH of 7.48
  • This example contemplates separation of product potassium formate from potassium carbonate/bicarbonate supporting electrolyte by membrane nano-filtration (NF) ( FIG. 10 ).
  • the test would involve two commercial NF membranes.
  • the feed solution would comprise 1.2M KHCO 3 +0.6M K-formate and its pH would be adjusted to 7, 9, and 11 for three separate runs (for each membrane).
  • [S] denotes molar concentration of solute that could be either formate or total carbonate.
  • a single permeation test could be performed with DK membrane, using a formate-enriched Feed solution comprising 1.2M KHCO 3 +1.2M K-formate.
  • the test could be done at pH 11 and all other conditions would be as in the above Example 1.
  • the same cell as in Examples 1, 2, and 3 was used, except for using 701 gm of tin shot (0.3-0.6 mm diameter) media with an electroless plated indium coating as the cathode.
  • the cathode compartment thickness was 0.875 inches.
  • the cell was operated in a batch condition with no overflow for the first 7.3 hrs, and then a 1.40 molar potassium bicarbonate feed was introduced into the catholyte at a rate of about 1.4 mL/min, with the overflow collected and measured, and a sample of the loop was collected for formate concentration analysis.
  • Catholyte flow rate 3.2 LPM Applied cell current: 6 amps (6,000 mA)
  • Catholyte pH range Dropping slowly from around a pH of 8 linearly with time during the run to a final pH of 7.50
  • the formate Faradaic efficiency was between 42% and 52% during the batch run period where the formate concentration went up to 10,490 ppm. During the feed and overflow period, the periodic calculated efficiencies varied between 32% and 49%. The average conversion efficiency was about 44%. The formate concentration varied between 10,490 and 48,000 ppm during the feed and overflow period. The cell voltage began at around 4.05 volts, ending up at 3.80 volts.
  • Electrolyses were performed using a 3-compartment glass cell of roughly 80 mL total volume.
  • the cell was constructed to be gas tight with Teflon bushings.
  • the compartments were separated by 2 glass frits.
  • a 3-electrode assembly was employed.
  • One compartment housed the working electrode and the reference electrode (Accumet silver/silver chloride) which contained the aqueous electrolyte and catalyst as stated.
  • the center compartment also contained the electrolyte and catalyst solution as stated.
  • the third compartment was filled with 0.5 molar K 2 SO 4 aqueous electrolyte solution sparged with CO 2 with a pH of about 4.5 and housed the counter electrode (TELPRO (Stafford, Tex.)—Mixed Metal Oxide Electrode).
  • the working electrode compartment was purged with carbon dioxide during the experiment.
  • the solutions were measured by ion chromatography for formic acid, analyzing the solution before (a blank) and after electrolysis.
  • the tests were conducted under potentiometric conditions using a 6 channel Arbin Instruments MSTAT, operating at ⁇ 1.46 or ⁇ 1.90 volts vs. an SCE reference electrode for about 1.5 hrs.
  • the same cell as in Examples 1, 2, and 3 was used, except for using 890.5 gm of tin shot (3 mm diameter) media and with a tin foil coating as the cathode.
  • the cathode compartment thickness was 1.25 inches and the system was operated in a batch mode with no feed input. Carbon dioxide was sparged to saturate the solution in the catholyte disengager.
  • the cell was operated in a batch condition with no overflow and a sample of the catholyte loop was collected for formate concentration analysis periodically.
  • the formate Faradaic efficiency started at about 65% and declined after 10 hours to 36% and to about 18.3% after 19 hours.
  • the final formate concentration ended up at 20,500 ppm at the end of the 19 hour run. See FIGS. 11 and 12 .
  • Example 1 The same cell as in Examples 1, 2, and 3 was used, except for using 805 gm of indium coated tin shot (3 mm diameter) media and with a 0.010 inch (0.0254 cm) thickness indium foil mounted on the 316L SS back conductor plate using a conductive silver epoxy as the cathode.
  • the cathode compartment thickness was 1.25 inches and the system was operated in a batch mode with no feed input. Carbon dioxide was sparged to saturate the solution in the catholyte disengager.
  • the tin shot was electrolessly plated with indium in the same method as used in Examples 1-4 on the tin-coated copper mesh.
  • the indium coating was estimated to be about 0.5-1.0 microns in thickness.
  • the cell was operated in a batch condition with no overflow and a sample of the catholyte loop was collected for formate concentration analysis periodically.
  • the formate Faradaic efficiency started at about 100% and varied between 60% to 85%, ending at about 60% after 24 hours.
  • the final formate concentration ended up at about 60,000 ppm at the end of the 24 hour run. Dilution error of the samples at the high formate concentrations may have provided the variability seen in the yield numbers. See FIGS. 13 and 14 .
  • the same cell as in Examples 1, 2, and 3 was used with a newly prepared indium on tin electrocatalyst coating on a copper mesh cathode.
  • the prepared cathode had calculated surface areas of about 3,171 cm 2 , for an area about 31 times the flat cathode plate area, with a 91% void volume, and specific surface area of 12.3 cm 2 /cm 3 .
  • the cells were operated in a recirculating batch mode for the first 8 hours of operation to get the catholyte formate ion concentration up to about 20,000 ppm, and then a fresh feed of 1.4 M potassium bicarbonate was metered into the catholyte at a feed rate of about 1.2 mL/min.
  • the overflow volume was collected and volume measured, and the overflow and catholyte loop sample were sampled and analyzed for formate by ion chromatography.
  • Cathode Electroless indium on tin on a copper mesh substrate Continuous Feed with Catholyte Recirculation Run—11.5 days
  • Catholyte flow rate 3.2 LPM
  • Catholyte flow velocity 0.09 ft/sec
  • Applied cell current 6 amps (6,000 mA)
  • the same cell as in Examples 1, 2, and 3 was used with a newly prepared indium on tin electrocatalyst coating on a copper mesh cathode.
  • the prepared cathode had calculated surface areas of about 3,171 cm 2 , for an area about 31 times the flat cathode plate area, with a 91% void volume, and specific surface area of 12.3 cm 2 /cm 3 .
  • the cells were operated in a recirculating batch mode for the first 8 hours of operation to get the catholyte formate ion concentration up to about 20,000 ppm, and then a fresh feed of 1.4 M potassium bicarbonate was metered into the catholyte at a feed rate of about 1.2 mL/min.
  • the overflow volume was collected and volume measured, and the overflow and catholyte loop sample were sampled and analyzed for formate by ion chromatography.
  • Cathode Electroless indium on tin on a copper mesh substrate Continuous Feed with Catholyte Recirculation Run—21 days
  • Catholyte flow rate 3.2 LPM
  • Catholyte flow velocity 0.09 ft/sec
  • FIG. 21 illustrates calculated formate current efficiency versus time measuring the formate yield from the collected samples. The formate Faradaic current efficiency declined down into the 20% range after 16 days.
  • FIG. 22 illustrates results of the formate concentration versus time.
  • 0.5 gm of indium (III) carbonate was added to the catholyte while the cell was still operating at the 6 ampere operating rate.
  • the formate concentration in the catholyte operating loop was 11,330 ppm before the indium addition, which increased to 13,400 ppm after 8 hours, and increased to 14,100 ppm after 16 hours when the unit was shut down after 21 days of operation.
  • FIG. 23 illustrates the catholyte pH change over the continuous operation period, which operated in the 7.6 to 7.7 pH range except for an outlier data point near day 16 when the feed pump had stopped pumping.
  • the feed rate was not changed during the run, but could have been increased or decreased to maintain a constant pH operation in an optimum range.

Landscapes

  • Chemical & Material Sciences (AREA)
  • Organic Chemistry (AREA)
  • Engineering & Computer Science (AREA)
  • Chemical Kinetics & Catalysis (AREA)
  • Electrochemistry (AREA)
  • Materials Engineering (AREA)
  • Metallurgy (AREA)
  • Electrolytic Production Of Non-Metals, Compounds, Apparatuses Therefor (AREA)

Abstract

Methods and systems for electrochemical conversion of carbon dioxide to organic products including formate and formic acid are provided. A system may include an electrochemical cell including a cathode compartment containing a high surface area cathode and a bicarbonate-based catholyte saturated with carbon dioxide. The high surface area cathode may include an indium coating and having a void volume of between about 30% to 98. The system may also include an anode compartment containing an anode and an acidic anolyte. The electrochemical cell may be configured to produce a product stream upon application of an electrical potential between the anode and the cathode.

Description

    CROSS-REFERENCE TO RELATED APPLICATIONS
  • The present application claims the benefit under 35 U.S.C. §119(e) of U.S. Patent Application Ser. No. 61/701,237, filed Sep. 14, 2012, which is hereby incorporated by reference in its entirety.
  • The present application also claims the benefit under 35 U.S.C. §119(e) of U.S. Provisional Application Ser. No. 61/703,158 filed Sep. 19, 2012, U.S. Provisional Application Ser. No. 61/703,175 filed Sep. 19, 2012, U.S. Provisional Application Ser. No. 61/703,231 filed Sep. 19, 2012, U.S. Provisional Application Ser. No. 61/703,232, filed Sep. 19, 2012, U.S. Provisional Application Ser. No. 61/703,234, filed Sep. 19, 2012, U.S. Provisional Application Ser. No. 61/703,238 filed Sep. 19, 2012, U.S. Provisional Application Ser. No. 61/703,187 filed Sep. 19, 2012, U.S. Provisional Application Ser. No. 61/720,670 filed Oct. 31, 2012, U.S. Provisional Application Ser. No. 61/703,229 filed Sep. 19, 2012 and U.S. Provisional Application Ser. No. 61/675,938 filed Jul. 26, 2012. The U.S. Provisional Application Ser. No. 61/703,158 filed Sep. 19, 2012, U.S. Provisional Application Ser. No. 61/703,175 filed Sep. 19, 2012, U.S. Provisional Application Ser. No. 61/703,231 filed Sep. 19, 2012, U.S. Provisional Application Ser. No. 61/703,232, filed Sep. 19, 2012, U.S. Provisional Application Ser. No. 61/703,234, filed Sep. 19, 2012, U.S. Provisional Application Ser. No. 61/703,238 filed Sep. 19, 2012, U.S. Provisional Application Ser. No. 61/703,187 filed Sep. 19, 2012, U.S. Provisional Application Ser. No. 61/720,670 filed Oct. 31, 2012, U.S. Provisional Application Ser. No. 61/703,229 filed Sep. 19, 2012 and U.S. Provisional Application Ser. No. 61/675,938 filed Jul. 26, 2012 are hereby incorporated by reference in their entireties.
  • The present application incorporates by reference co-pending U.S. Patent application Attorney Docket 0017A, U.S. Patent application Attorney Docket 0022, U.S. Patent application Attorney Docket 0023, U.S. Patent application Attorney Docket 0024, U.S. Patent application Attorney Docket 0025U.S. Patent application Attorney Docket 0026, U.S. Patent application Attorney Docket 0027, U.S. Patent application Attorney Docket 0028, U.S. Patent application Attorney Docket 0029, and U.S. Patent application Attorney Docket 0030 in their entireties.
  • FIELD
  • The present disclosure generally relates to the field of electrochemical reactions, and more particularly to methods and/or systems for electrochemical reduction of carbon dioxide using high surface area electrodes.
  • BACKGROUND
  • The combustion of fossil fuels in activities such as electricity generation, transportation, and manufacturing produces billions of tons of carbon dioxide annually. Research since the 1970s indicates increasing concentrations of carbon dioxide in the atmosphere may be responsible for altering the Earth's climate, changing the pH of the ocean and other potentially damaging effects. Countries around the world, including the United States, are seeking ways to mitigate emissions of carbon dioxide.
  • A mechanism for mitigating emissions is to convert carbon dioxide into economically valuable materials such as fuels and industrial chemicals. If the carbon dioxide is converted using energy from renewable sources, both mitigation of carbon dioxide emissions and conversion of renewable energy into a chemical form that can be stored for later use may be possible.
  • SUMMARY OF THE PREFERRED EMBODIMENTS
  • The present invention is directed to using high surface area electrodes and particular electrolyte solutions to produce single carbon (C1) chemicals, including formic acid, and multi-carbon (C2+) based chemicals (i.e., chemicals with two or more carbon atoms in the compound). The present invention includes the process, system, and various components thereof.
  • It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not necessarily restrictive of the disclosure as claimed. The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate an embodiment of the disclosure and together with the general description, serve to explain the principles of the disclosure.
  • BRIEF DESCRIPTION OF THE DRAWINGS
  • The numerous advantages of the present disclosure may be better understood by those skilled in the art by reference to the accompanying figures in which:
  • FIG. 1 is a flow diagram of a preferred electrolyzer system for the reduction of carbon dioxide in accordance with an embodiment of the present disclosure;
  • FIG. 2 is a flow diagram of a preferred electrochemical acidification system;
  • FIG. 3 is a flow diagram of another preferred system for the electrochemical reduction of carbon dioxide;
  • FIG. 4 is a flow diagram of another preferred electrochemical acidification system incorporating bipolar membranes;
  • FIG. 5 is flow diagram of another preferred electrochemical electrolyzer system incorporating an ion exchange compartment for the reduction of carbon dioxide; and
  • FIG. 6 is a flow diagram of a nano-filtration system in accordance with an embodiment of the present disclosure;
  • FIG. 7 is a chart illustrating cumulative yield of formate over time in accordance with an embodiment described with reference to Example 1 of the present disclosure;
  • FIG. 8 is a chart illustrating cumulative yield of formate over time in accordance with an embodiment described with reference to Example 2 of the present disclosure;
  • FIG. 9 is a chart illustrating cumulative yield of formate over time in accordance with an embodiment described with reference to Example 3 of the present disclosure;
  • FIG. 10 is a chart illustrating cumulative yield of formate over time in accordance with an embodiment described with reference to Example 4 of the present disclosure;
  • FIG. 11 is a chart illustrating cumulative formate yield versus time in accordance with an embodiment described with reference to Example 9 of the present disclosure;
  • FIG. 12 is a chart illustrating formate concentration versus time in accordance with an embodiment described with reference to Example 9 of the present disclosure;
  • FIG. 13 is a chart illustrating cumulative formate yield versus time in accordance with an embodiment described with reference to Example 10 of the present disclosure;
  • FIG. 14 is a chart illustrating formate concentration versus time in accordance with an embodiment described with reference to Example 10 of the present disclosure;
  • FIG. 15 is a chart illustrating operating cell voltage versus time in accordance with an embodiment described with reference to Example 11 of the present disclosure;
  • FIG. 16 is a chart illustrating catholyte formate concentration versus time in accordance with an embodiment described with reference to Example 11 of the present disclosure;
  • FIG. 17 shows a scanning electron microscope (SEM) image of the electroless indium coating on tin-plated copper fiber cathode used in Example 11 of the present disclosure;
  • FIG. 18 shows an SEM image of an electroless indium coating on a treated carbon fiber material;
  • FIG. 19 is a chart illustrating formate current efficiency versus time in accordance with an embodiment described with reference to Example 11 of the present disclosure;
  • FIG. 20 is a chart illustrating catholyte pH versus time in accordance with an embodiment described with reference to Example 11 of the present disclosure;
  • FIG. 21 is a chart illustrating formate current efficiency versus time in accordance with an embodiment described with reference to Example 12 of the present disclosure;
  • FIG. 22 is a chart illustrating catholyte formate concentration versus time in accordance with an embodiment described with reference to Example 12 of the present disclosure; and
  • FIG. 23 is a chart illustrating catholyte pH versus time in accordance with an embodiment described with reference to Example 12 of the present disclosure.
  • DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
  • Reference will now be made in detail to the presently preferred embodiments of the present disclosure, examples of which are illustrated in the accompanying drawings.
  • In accordance with some embodiments of the present disclosure, an electrochemical system is provided that converts carbon dioxide to organic products including formate and formic acid. Use of a cathode comprising a high surface area three dimensional material, an acidic anolyte, and a catholyte comprising bicarbonate facilitates the process.
  • Before any embodiments of the invention are explained in detail, it is to be understood that the embodiments described below do not limit the scope of the claims that follow. Also, it is to be understood that the phraseology and terminology used herein is for the purpose of description and should not be regarded as limiting. The use of terms such as “including,” “comprising,” or “having” and variations thereof herein are generally meant to encompass the item listed thereafter and equivalents thereof as well as additional items. Further, unless otherwise noted, technical terms may be used according to conventional usage.
  • Referring to FIG. 1, a flow diagram of an electrolyzer system 100 is shown in accordance with an embodiment of the present invention. The electrolyzer system 100 may be utilized for the electrochemical reduction of carbon dioxide to organic products or organic product intermediates. Preferably, the electrolyzer system 100 reduces carbon dioxide to an alkali metal formate, such as potassium formate. The electrolyzer system 100 generally includes an electrolyzer 102, an anolyte recycle loop 104, and a catholyte recycle loop 106. The electrolyzer system 100 may include as process feeds/inputs carbon dioxide, a catholyte comprising bicarbonate (preferably potassium bicarbonate, but other bicarbonate-based compounds are contemplated instead of or in addition to potassium bicarbonate), and an acidic anolyte (preferably sulfuric acid, but may include other acids, instead of, or in addition to sulfuric acid). The product of the electrolyzer system 100 is generally an alkali metal formate, such as potassium formate, and may include excess catholyte, carbon dioxide, hydrogen, oxygen, and/or other unreacted process inputs.
  • The electrolyzer 102 generally includes an anode compartment 108 and a cathode compartment 110, and may further include a cation exchange membrane 112 to separate the anode compartment 108 from the cathode compartment 110. The anode compartment 108 includes an anode 114 suitable to oxidize water. In a preferred implementation, the anode 114 is a titanium anode having an anode electrocatalyst coating which faces the cation exchange membrane 112. For instance, the anode 114 may include an anode mesh screen 116 that includes a folded expanded titanium screen with an anode electrocatalyst coating. The anode mesh screen 116 may provide spacing and contact pressure between the anode 114 and the cation exchange membrane 112. The anode 114 may also include one or more electrical current connection posts (not shown) on a backside of the anode 114.
  • The cathode compartment 110 generally includes a cathode 118 mounted within the cathode compartment 110. The cathode 118 preferably includes a metal electrode with an active electrocatalyst layer on a front surface of the cathode 118 facing the cation exchange membrane 112, and may include one or more electrical current conduction posts (not shown) on a backside of the cathode 118. The cathode 118 preferably includes a high surface area cathode structure 120. The high surface area cathode structure 120 may be mounted between the cation exchange membrane 112 and the cathode 118 for conducting electrical current into the high surface area cathode structure 120. The interface between the high surface area cathode structure 120 and the cation exchange membrane 112 may include an insulator screen (not shown), such as a thin expanded plastic mesh insulator screen to minimize direct contact between the high surface area cathode structure 120 and the cation exchange membrane 112.
  • The anode compartment 108 generally includes an anode feed stream 122 that includes a dilute acid anolyte solution. The anode feed stream 122 may enter a bottom of the anode compartment 108 to flow by a face of the anode 114 and through the anode mesh screen 116. The reaction in the anode compartment 108 may include deriving oxygen (O2, i.e., gaseous oxygen) and hydrogen ions (H+) or protons from the oxidation of water at an applied current and voltage potential. The hydrogen ions or protons are generally available for the reactions within the cathode compartment 110 via the cation exchange membrane 112. The gaseous oxygen and other liquids leaving the anode compartment 108 of the electrolyzer 102 leave as anode exit stream 124. The anode exit stream 124 may be monitored by a temperature sensor 126 a and may flow to an anolyte disengager 128 suitable for separating the oxygen from the anode exit stream 124. The anolyte disengager 128 may process the anode exit stream 124 into an oxygen stream 130, an anolyte recycle stream 132, and an anolyte overflow stream 134. The oxygen stream 130 may be vented from the anolyte disengager 128. The anolyte stream 132 may be combined with water (preferably deionized water) from a water source 136 and with acid (preferably sulfuric acid) from an acid source 138. The water source 136 and the acid source 138 in the anolyte recycle loop 104 may maintain anolyte acid strength and volume for the anode feed stream 122. The temperature of the anode feed stream 122 may be regulated by a heat exchanger 140 a coupled with a cooling water source 142 a prior to entering the anode compartment 108 of the electrolyzer 102.
  • The cathode compartment 110 generally includes a cathode feed stream 144 that includes carbon dioxide and a catholyte. In a preferred implementation, the catholyte is a bicarbonate compound, such as potassium bicarbonate (KHCO3), which is saturated with carbon dioxide. The cathode feed stream 144 may enter a bottom of the cathode compartment 110 to flow by a face of the cathode 118 and through the high surface area cathode structure 120. The reaction in the cathode compartment 110 may reduce carbon dioxide to formate at an applied current and voltage potential. The reaction products and any unreacted materials (e.g., excess catholyte solution) may exit the cathode compartment 110 as cathode exit stream 146. The cathode exit stream 146 may be monitored by a pH sensor 148 a and a temperature sensor 126 b and may flow to a catholyte disengager 150 suitable for separating gaseous components (e.g., hydrogen) from the cathode exit stream 146. The catholyte disengager 150 may process the cathode exit stream 146 into a hydrogen stream 152, a product stream 154, and a catholyte recycle stream 156. The hydrogen stream 152 may be vented from the catholyte disengager 150. The product stream 154 preferably includes an alkali metal formate (such as potassium formate where the electrolyte includes potassium bicarbonate) and may include excess catholyte. The catholyte stream 156 may be processed by a catholyte recirculation pump 158 and a heat exchanger 140 b coupled with a cooling water source 142 b. A temperature sensor 126 c may monitor the catholyte stream 156 downstream from the heat exchanger 140 b having cooling water source 142 b. A fresh catholyte electrolyte feed 160 may be metered into the catholyte stream 156, where the fresh catholyte electrolyte feed 160 may adjust the pH of the cathode feed stream 144 into the cathode compartment 110 of the electrolyzer 102, which may control final product overflow rate and establish the formate product concentration. The pH may be monitored by pH sensor 148 b. A carbon dioxide stream 162 may be metered into the cathode feed stream 144 downstream from the catholyte electrolyte feed 160 prior to entering the cathode compartment 110 of the electrolyzer 102. Preferably, the carbon dioxide saturates the catholyte entering the cathode compartment.
  • When using an acidic anolyte, where protons are passed through the membrane into the cathode compartment, the pH of the electrolyzer 102 may be controlled or maintained through use of an alkali metal bicarbonate and/or carbonate in combination with water to control the pH of the catholyte. By controlling the pH of the catholyte at an optimum value, the cell may more efficiently convert carbon dioxide into C1 and C2 products with a higher conversion rate than if a non-optimum pH value was maintained or if no pH control mechanism was employed. In a preferred process, the catholyte is constantly recirculated to maintain an adequate and uniform carbon dioxide concentration at cathode surfaces coated with an electrocatalyst. A fresh catholyte feed stream may be used to control the pH of the catholyte and to control the product concentration in the product overflow stream. The mass flow rate of the catholyte feed to the cathode compartment (e.g., mass flow of potassium bicarbonate) is preferably balanced with the introduction of protons into the catholyte and with the formation of hydroxide from the inefficient byproduct reaction of water splitting at the cathode. The concentration of the potassium bicarbonate is important, since it provides volume to the catholyte, which will dilute the product in the catholyte.
  • For pH control of the catholyte, potassium bicarbonate is preferred, in a concentration range of 5 to 600 gm/L, or more preferably in the 10 to 500 gm/L range. If the feed concentration of bicarbonate to the catholyte is fixed, a separate feed of water may be employed into the catholyte to control final product concentration. In another implementation, potassium carbonate may be used as a feed for pH control. Potassium carbonate has a much higher solubility in water than potassium bicarbonate, and is preferably used in a concentration range of 5 to 1,500 gm/L.
  • Referring now to FIG. 2, a block diagram of an electrochemical acidification system 200 is shown in accordance with an embodiment of the present invention. The electrochemical acidification system 200 may be utilized to acidify the product stream 154 from the electrolyzer system 100. Preferably, the electrochemical acidification system 200 acidifies an alkali metal formate, such as potassium formate, to form an organic acid, such as formic acid, and co-produce an alkali metal hydroxide, such as potassium hydroxide. The electrochemical acidification system 200 generally includes an electrochemical acidification unit 202, an anolyte recycle loop 204, and a catholyte recycle loop 206. The electrochemical acidification system 200 may include as process feeds/inputs the product stream 154 from the electrolyzer system 100 (which preferably includes an alkali metal formate), water in each of the anolyte recycle loop 204 and the catholyte recycle loop 206, and an acidic anolyte (preferably sulfuric acid, but may include other acids, instead of, or in addition to sulfuric acid). The product of the electrochemical acidification system 200 is generally an organic acid, such as formic acid, and an alkali metal hydroxide, and may include residual alkali metal formate, bicarbonate catholyte, carbon dioxide, hydrogen, oxygen, and/or other unreacted process inputs.
  • The electrochemical acidification unit 202 is preferably a three-compartment electrochemical acidification unit or cell. The electrochemical acidification unit 202 generally includes an anode compartment 208, a cathode compartment 210, and a central ion exchange compartment 212 bounded by cation exchange membranes 214 a and 214 b on each side. The anode compartment 208 includes an anode 216 suitable to oxidize water. In a preferred implementation, the anode 216 is a titanium anode having an anode electrocatalyst coating which faces the cation exchange membrane 214 a. The cathode compartment 210 includes a cathode 218 suitable to reduce water and to generate an alkali metal hydroxide. In a preferred implementation, hydrogen ions (H+) or protons are generated in the anode compartment 208 when a potential and current are applied to the electrochemical acidification unit 202. The hydrogen ions (H+) or protons pass through the cation exchange membrane 214 a into the central ion exchange compartment 212. The product stream 154 from the electrolyzer system 100 is preferably introduced to the electrochemical acidification unit 202 via the central ion exchange compartment 212, where the hydrogen ions (H+) or protons displace the alkali metal ions (e.g., potassium ions) in the product stream 154 to acidify the stream and produce a product stream 260 including an organic acid product, preferably formic acid. The displaced alkali metal ions may pass through the cation exchange membrane 214 b to the cathode compartment 210 to combine with hydroxide ions (OH) formed from water reduction at the cathode 218 to form an alkali metal hydroxide, preferably potassium hydroxide.
  • The central ion exchange compartment 212 may include a plastic mesh spacer (not shown) to maintain the dimensional space in the central ion exchange compartment 212 between the cation exchange membranes 214 a and 214 b. In an embodiment, a cation ion exchange material 220 is included in the central ion exchange compartment 212 between the cation exchange membranes 214 a and 214 b. The cation ion exchange material 220 may include an ion exchange resin in the form of beads, fibers, and the like. It is contemplated that the cation ion exchange material 220 may increase electrolyte conductivity in the ion exchange compartment solution, and may reduce the potential effects of carbon dioxide gas on the cell voltage as bubbles are formed and pass through the central ion exchange compartment 212.
  • The anode compartment 208 generally includes an anode feed stream 222 that includes an acid anolyte solution (preferably a sulfuric acid solution). The gaseous oxygen and other liquids leaving the anode compartment 208 of the electrochemical acidification unit 202 leave as anode exit stream 224. The anode exit stream 224 may be monitored by a temperature sensor 226 a and may flow to an anolyte disengager 228 suitable for separating the oxygen from the anode exit stream 224. The anolyte disengager 228 may process the anode exit stream 224 into an oxygen stream 230, an anolyte recycle stream 232, and an anolyte overflow stream 234. The oxygen stream 230 may be vented from the anolyte disengager 228. The anolyte stream 232 may be combined with water (preferably deionized water) from a water source 236 and with acid (preferably sulfuric acid) from an acid source 238. The water source 236 and the acid source 238 in the anolyte recycle loop 204 may maintain anolyte acid strength and volume for the anode feed stream 222. The temperature of the anode feed stream 222 may be regulated by a heat exchanger 240 a coupled with a cooling water source 242 a prior to entering the anode compartment 208 of the electrochemical acidification unit 202.
  • The cathode compartment 210 generally includes a catholyte feed stream 244 that includes water and may include an alkali metal hydroxide that circulates through the catholyte recycle loop 206. The reaction products, which may include the alkali metal hydroxide and hydrogen gas, may exit the cathode compartment 210 as cathode exit stream 246. The cathode exit stream 246 may be monitored by a temperature sensor 226 b and may flow to a catholyte disengager 248 suitable for separating gaseous components (e.g., hydrogen) from the cathode exit stream 246. The catholyte disengager 248 may process the cathode exit stream 246 into a hydrogen stream 250, a catholyte stream 252, and a catholyte overflow stream 254, which may include KOH. The hydrogen stream 250 may be vented from the catholyte disengager 248. The catholyte stream 252 preferably includes an alkali metal hydroxide (such as potassium hydroxide where the product steam 154 includes potassium formate). The catholyte stream 252 may be processed by a catholyte recirculation pump 256 and a heat exchanger 240 b coupled with a cooling water source 242 b. A temperature sensor 226 c may monitor the catholyte stream 252 downstream from the heat exchanger 240 b. The catholyte stream 252 may be combined with water (preferably deionized water) from a water source 258, where the water may be metered to control the concentration of the alkali metal hydroxide in the catholyte feed stream 244 entering the cathode compartment 210.
  • Referring now to FIG. 3, a flow diagram of a preferred system 300 for the electrochemical reduction of carbon dioxide to an organic acid product is shown. The system 300 may incorporate the electrolyzer system 100 (described with reference to FIG. 1) and the electrochemical acidification system 200 (described with reference to FIG. 2), and preferably includes a potassium hydroxide recycle loop 302 suitable for the production of potassium bicarbonate from potassium hydroxide and carbon dioxide. The system 300 may also incorporate carbon dioxide processing components for the separation (e.g., gas separation units 304 a, 304 b, 304 c, 304 d) and recovery of carbon dioxide from process streams.
  • The system 300 generally includes carbon dioxide, an alkali metal hydroxide (preferably potassium hydroxide), an acid (preferably sulfuric acid), and water (preferably deionized water) as process inputs and generally includes an organic acid (preferably formic acid), oxygen gas, and hydrogen gas as process outputs. The organic acid may undergo additional processing to provide a desired form and concentration. Such processing may include evaporation, distillation, or another suitable physical separation/concentration process.
  • The chemistry of the reduction of carbon dioxide in the system 300 may be as follows.
  • Hydrogen atoms are adsorbed at the electrode from the reduction of water as shown in equation (1).

  • H+ +e →Had  (1)
  • Carbon dioxide is reduced at the cathode surface with the adsorbed hydrogen atom to form formate, which is adsorbed on the surface as in equation (2).

  • CO2+Had→HCOOad  (2)
  • The adsorbed formate on the surface then reacts with another adsorbed hydrogen atom to form formic acid that is then released into the solution as in equation (3)

  • HCOOad+Had→HCOOH  (3)
  • The competing reaction at the cathode is the reduction of water where hydrogen gas is formed as well as hydroxide ions as in equation (4).

  • 2H2O+2e →H2+2OH  (4)
  • The anode reaction is the oxidation of water into oxygen and hydrogen ions as shown in equation (5).

  • 2H2O→4H++4e +O2  (5)
  • High Surface Area Cathode
  • As described with reference to FIG. 1, the cathode 118 preferably includes a high surface area cathode structure 120. The high surface area cathode structure 120 preferably includes a void volume ranging from 30% to 98%. The specific surface area of the high surface area cathode structure 120 is preferably from 2 cm2/cm3 to 500 cm2/cm3 or higher. The surface area also can be defined as total area in comparison to the current distributor/conductor back plate, with a preferred range of 2× to 1000× or more.
  • The cathode 118 preferably includes electroless indium on tin (Sn) coated copper woven mesh, copper screen, copper fiber as well as bronze and other are copper-tin alloys, nickel and stainless steels. The metals may be precoated with other metals, such as to adequately form a suitable base for the application of the indium and other preferred cathode coatings. The cathode may also include Indium-Cu intermetallics formed on the surfaces of copper fiber, woven mesh, copper foam or copper screen. The intermetallics are generally harder than the soft indium metal, and may provide desirable mechanical properties in addition to usable catalytic properties. The cathode may also include, but is not limited to coatings and/or metal structures containing Pb, Sn, Hg, Tl, In, Bi, and Cd, their alloys, and combinations thereof. Metals including Ti, Nb, Cr, Mo, Ag, Cd, Hg, Tl, An, and Pb as well as Cr—Ni—Mo steel alloys among many others may be incorporated. The cathode 118 may include a single or multi-layered electrode coating, such that the electrocatalyst coating on the cathode substrate includes one or more layers of metals and alloys. A preferred electrocatalyst coating on the cathode includes a tin coating on a high surface area copper substrate with a top layer/coating of indium. The indium coating coverage preferably ranges from 5% to 100% as indium.
  • In the use of indium alloys on the exposed catalytic surfaces of the electrode, the indium composition preferably ranges from 5% to 99% as indium in alloys with other metals, including Sn, Pb, Hg, Tl, Bi, Cu, and Cd and their mixed alloys and combinations thereof. It is also contemplated to include Au, Ag, Zn, and Pd into the coating in percentages ranging from 1% to 95%.
  • Additionally, metal oxides may be used or prepared as electrocatalysts on the surfaces of the base cathode structure. For example, lead oxide can be prepared as an electrocatalyst on the surfaces of the base cathode structure. The metal oxide coating could be formed by a thermal oxidation method or by electro-deposition followed by chemical or thermal oxidation.
  • Additionally, the cathode base structure can also be gradated or graduated, such that the density of the cathode can be varied in the vertical or horizontal directions in terms of density, void volume, or specific surface area (e.g., varying fiber sizes). The cathode structure may also consist of two or more different electrocatalyst compositions that are either mixed or located in separate regions of the cathode structure in the catholyte compartment.
  • During normal operation of the electrolyzer 102, the performance of the system may decrease with regard to formate yield which may result from catalyst loss or over-coating of the catalyst with impurities, such as other metals that may be plated onto the cathode 118. The surfaces of the cathode 118 may be renewed by the periodic addition of indium salts or a mix of indium/tin salts in situ during operation of the electrolyzer 102. Depending on the composition of the cathode 118, it is contemplated that other or additional metal salts may be added in situ including salts of Ag, Au, Mo, Cd, Sn, and other suitable metals, singly or in combination. The electrolyzer 102 may be operated at full rate during operation, or temporarily operated at a lower current density with or without any carbon dioxide addition during the injection of the metal salts. The conditions under which to renew the cathode surface with the addition of these salts may differ depending on desired renewal results. The use of an occasional brief current reversal during electrochemical cell operation may also be employed to potentially renew the cathode surfaces.
  • In particular embodiments, the electrolyzer 102 is operated at pressures exceeding atmospheric pressure, which may result in higher current efficiency and permit operation of the electrolyzer 102 at higher current densities than when operating the electrolyzer 102 at or below atmospheric pressure.
  • In preparing cathode materials for the production of organic chemicals, the addition of metal salts that can reduce on the surfaces of the cathode structure can be also used, such as the addition of Ag, Au, Mo, Cd, Sn, and other suitable metals. Such addition of metal salts may provide a catalytic surface that may be otherwise difficult to prepare directly during cathode fabrication or for renewal of the catalytic surfaces.
  • A preferred method for preparing the high surface area cathode structure 120 is using an electroless plating solution which may include an indium salt, at least one complexing agent, a reducing agent, a pH modifier, and a surfactant. The preferred procedure for forming an electroless indium coating on the high surface area cathode may include combining in stirred deionized water the following materials: Trisodium citrate dihydrate (100 g/L), EDTA-disodium salt (15 g/L), sodium acetate (10 g/L), InCl3 (anhydrous, 10 g/L), and Thiodiglycolic acid (0.3 g/L, e.g., 3 mL of 100 mg/mL solution). A pre-mixed stock deposition solution that has been stirred (preferably for multiple hours, e.g., overnight) may also be used. The procedure also includes heating the mixture to about 40° C. The procedure also includes adding 40 mL TiCl3 (20 wt. % in 2% HCl) per liter [0.05 mM] and adding 7M ammonia in methanol until the pH of the mixture is approximately 7 (˜15 mL ammonia solution per liter) at which point ammonium hydroxide (28% ammonia solution) is used to adjust the pH to between approximately 9.0 and 9.2. The procedure then includes heating the mixture to about 60° C. If the pH drops, adjust the pH to approximately 9.0 with ammonium hydroxide solution. The procedure then includes heating the mixture to about 75° C., where deposition may begin at about 65° C. The procedure includes holding the mixture at 75° C. for about one hour.
  • A preferred procedure for the metallic coating of copper substrates may include rinsing bare copper substrates in acetone to clean the copper surface (e.g., removing residual oils or grease that may be present on the copper surface) and then rinsing the acetone-treated copper substrates in deionized water. The procedure also includes immersing the bare copper substrates in a 10% sulfuric acid bath for approximately 5 minutes, and then rinsing with deionized water. The procedure also includes depositing approximately 25 μm of tin on the copper surface. The deposition may be done using a commercial electroless tinning bath (Caswell, Inc.) operated at 60° C. for 15 minutes. Following tin deposition, parts are rinsed thoroughly in deionized water. The procedure also includes depositing approximately 1 μm of indium on the tinned copper surface. The deposition may be done using an electroless bath operated at 90° C. for 60 minutes. Following indium deposition, parts are rinsed thoroughly in deionized water. The procedure may also include treated the copper/tin/indium electrode in a 5 wt % nitric acid bath for 5 minutes. Such treatment may improve electrode stability as compared to an untreated copper/tin/indium electrode. In another implementation, the electroless tin plated copper substrate may be dipped into molten indium for coating.
  • In particular implementations, cathode substrates may be treated with catalytic materials for carbon dioxide reduction. Four example treatments are presented by the following.
  • A first treatment may include coating a conductive substrate (e.g., vitreous carbon or metal) in a conductive sol-gel containing sufficient catalyst material to yield a high active surface area. The conductive component of the sol-gel may be catalytically active. After coating the substrate with the catalytic sol-gel, the sol-gel is allowed to undergo a high degree of polymerization/cross-linking. The combined substrate/sol-gel structure may then be pyrolized at high temperature to convert organic material to amorphous (and potentially conductive) carbon. The pyrolized structure may also be subjected to chemical treatments that selectively remove the organic material or the silica phase, leading to a high catalyst content coating.
  • The second treatment may include binding relatively small particles (e.g., micron or nanometer scale) to a substrate using a binding agent such as amines, thiols, or other suitable binding agent. The binding agent is preferably conductive to pass current between the substrate and catalyst particles. The catalyst particles preferably include conjugated organic molecules, such as diphenybenzene. If the substrate is also made of catalyst material the binding agent may have symmetrical binding groups, otherwise binding agents with two different binding groups may be utilized.
  • The third treatment may include coating a substrate in a slurry containing catalyst material (which may be in salt form) and a binding agent. The slurry may also contain a conductive additive, such as carbon black, carbon nanotubes, or other suitable conductive additive. The slurry coating may then be dried to form a conformal coating over the substrate. The substrate and dried slurry coating may be heated in order to fuse the various constituent materials into a mechanically robust, conductive, and catalytic material. In a particular implementation, the heating of the substrate and dried slurry coating occurs in a reducing environment.
  • The fourth treatment may include coating a substrate with semiconducting metal chalcogenides by applying a precursor to the substrate, removing solvent, and baking the substrate to convert the precursor material to a monolithic semiconducting metal chalcogenide coating. The coating materials may include, but are not limited to, Na4SnS4, Na4Sn2S6, K4SnTe4, Na3AsS3, (NH4)4Sn2S6, (NH4)3AsS3, and (NH4)2MoS4.
  • Other coating and electrocatalyst preparation techniques include applying thermal oxides onto a substrate, forming an intermetallic with a substrate, and applying semiconductor materials on a substrate. In an embodiment, the thermal oxidation of various metal salts painted onto various metal and ceramic substrates is preferred for forming high surface area materials suitable for the electrochemical reduction of carbon dioxide. The thermal oxidation may be similar to that used for forming electrocatalysts on titanium for use as anode materials in electrochemical chlorine cells, such as iridium oxide and ruthenium oxide. In another embodiment, indium is electroplated onto a copper foil, then the copper foil is heated to 40° C. above the melting point of indium, until indium is melted on the foil surface, and forming a golden intermetallic with copper, and then cooled. The formation of the intermetallic can be done in air or under an inert gas atmosphere (e.g., argon or helium) or under a full or partial vacuum. The electroplated material preferably provides approximately 50% Faradaic conversion efficiency, and may be utilized as a coating on planar metal back plates and also on copper fibers. An intermetallic may also be formed with tin-plated copper substrates. In a further embodiment, a semiconductor material may be applied to a substrate by gaseous deposition, sputtering, or other suitable application methods. The substrate is preferably a metallic substrate. The semiconductor materials may be doped to P-type or N-type as desired.
  • In the four treatments and other coating techniques described above, certain measures may be taken to improve the quality (mechanical, electrical, etc.) of the bond between the substrate and catalyst. Such measures may involve creating functional groups on the substrate surface that can undergo chemical bonding with the catalyst or a binding agent, or the creation of geometrical features in the substrate surface that facilitate bonding with an applied catalyst coating.
  • The substrate for the high surface area cathodes described herein may include RVC materials, such as carbon and graphite, metal foams, woven metals, metal wools made from fibers, sintered powder metal films and plates, metal and ceramic beads, pellets, ceramic and metal column and trickle bed packing materials, metal and inorganic powder forms, metal fibers and wools, or other suitable substrate materials. The specific surface area of the physical forms preferably include a specific surface area between approximately 2 and 2,000 cm2/cm3 or greater.
  • The electrode or high surface area structure of an electrode may incorporate alloys as fibers or wools, and may be coated with various compounds, and subsequently fired in air or in a reducing atmosphere oven, to form stable oxides on the surfaces which are electrocatalytic in the reduction of carbon dioxide. Other cathode materials may include metallic glasses and amorphous metals.
  • Referring now to FIG. 4, a particular implementation of the acid acidification system 200 of FIG. 2 is shown utilizing bipolar membranes in an electrochemical acidification unit 402. By utilizing bipolar membranes in electrochemical acidification unit 402, the alkali metal formate (e.g., potassium formate) may be acidified in addition to recovering potassium hydroxide. The use of the bipolar membranes may reduce the voltage required for the acidification of the alkali metal formate and may reduce the number of actual anodes and cathodes needed for the electrochemical stack. The bipolar membranes preferably consist of a cation membrane and an anion membrane that have been bonded together, and function by splitting water at the two membrane interface, forming hydrogen (H+) ions from the cation membrane and hydroxide ions (OH) from the anion membrane.
  • Referring now to FIG. 5, an alternative embodiment of the electrochemical system 100 of FIG. 1 is shown. The electrolyzer 502 in FIG. 5 includes an ion exchange compartment 504 in addition to an anode 506 compartment and a cathode compartment 508. This ion exchange compartment 504 functions similarly as the acid acidification compartment 212 in electrochemical acidification unit 202 as shown in FIG. 2. The alkali metal formate product (e.g., potassium formate) and unreacted KHCO3 from the cathode compartment is passed through the ion exchange compartment 504 to provide a formic acid product with CO2 and some residual KHCO3. The hydrogen ions (H+) passing through the adjacent membrane 510 a on the anode compartment side displace the alkali metal ions (e.g., K+) in the stream passing through the central ion exchange compartment 504 so that the alkali metal formate is acidified and the alkali metal ions and remaining hydrogen ions pass through the adjoining membrane 510 b on the cathode compartment 508 and into the catholyte. This will allow operation of the catholyte at higher pH conditions if required for obtaining high Faradaic current efficiencies with the cathodes selected for the process.
  • In an indium-based cathode system, the preferred catholytes include alkali metal bicarbonates, carbonates, sulfates, phosphates, and the like. Other preferred catholytes include borates, ammonium, and hydroxides. Other catholytes may include chlorides, bromides, and other organic and inorganic salts. Non-aqueous electrolytes, such as propylene carbonate, methanesulfonic acid, methanol, and other ionic conducting liquids may be used, which may be in an aqueous mixture, or as a non-aqueous mixture in the catholyte. The introduction of micro bubbles of carbon dioxide into the catholyte stream may improve carbon dioxide transfer to the cathode surfaces.
  • Referring now to FIG. 6, a nano-filtration system may be utilized between the electrolyzer system 100, as shown in FIG. 1, and the electrochemical acidification system 200, as shown in FIG. 2. The nano-filtration system is preferably utilized to separate alkali metal formate (e.g., potassium formate) from bicarbonate leaving the electrolyzer system 100 (e.g., stream 154) to reduce the amount of bicarbonate entering the electrochemical acidification unit 202. The nano-filtration system preferably uses a nano-filtration filter/membrane under pressure for selective separation of the bicarbonate from the alkali metal formate. The nano-filtration filter/membrane separates monovalent anions (e.g., formate) from divalent anions (e.g., carbonate) using a high pressure pump and suitable selected membranes for the separation. When utilizing the nano-filtration system as a separation tool between the electrolyzer system 100 and the electrochemical acidification system 200, the bicarbonate in the formate/bicarbonate product (e.g., stream 154) is preferably converted to carbonate in order to efficiently separate the formate from the carbonate with the nano-filtration filter/membrane. The nano-filtration system may include a mixer, such as a mixing tank, to mix the formate/bicarbonate product stream with a potassium hydroxide (KOH) stream. The mixer may promote the conversion of potassium bicarbonate to potassium carbonate to facilitate the separation of the formate from the carbonate. A high pressure pump then sends the potassium formate/carbonate stream into a nano-filtration unit which includes the nano-filtration filter/membrane. The nano-filtration unit produces a low-carbonate-containing potassium formate permeate stream which is then sent to the electrochemical acidification system 200 as shown in FIG. 2 as stream 154, to enter the electrochemical acidification unit 202. The potassium carbonate containing reject stream leaving the nano-filtration unit is preferably sent to the KHCO3 block of FIG. 3, where the potassium carbonate is mixed with KOH and CO2 for conversion to potassium bicarbonate. The potassium bicarbonate is preferably utilized as a feed to the cathode compartment of the electrolyzer 102 of the electrolyzer system 100. The nano-filtration separation system may consist of multiple units connected in a series flow configuration to increase the total separation efficiency of the carbonate from formate separation. The system may also utilize recycle streams to recycle an output stream from one unit to the input of another unit to maintain flow and pressures as well as to increase the recovery of the formate.
  • Depending on the chemistry of the electrochemical systems described herein, the pH of the catholyte preferably ranges from 3 to 12. The desired pH of the catholyte may be a function of the catholyte operating conditions and the catalysts used in the cathode compartment, such that there is limited or no corrosion at the electrochemical cell.
  • Preferable catholyte cross sectional area flow rates may include a range of 2 to 3,000 gpm/ft2 or more (0.0076 to 11.36 m3/m2), with a flow velocity range of 0.002 to 20 ft/sec (0.0006 to 6.1 m/sec).
  • A homogenous heterocyclic catalyst is preferably utilized in the catholyte. The homogenous heterocyclic catalyst may include, for example, one or more of 4-hydroxy pyridine, adenine, a heterocyclic amine containing sulfur, a heterocyclic amine containing oxygen, an azole, a benzimidazole, a bipyridine, furan, an imidazole, an imidazole related species with at least one five-member ring, an indole, a lutidine, methylimidazole, an oxazole, phenanthroline, pterin, pteridine, a pyridine, a pyridine related species with at least one six-member ring, pyrrole, quinoline, or a thiazole, and mixtures thereof.
  • Preferred anolytes for the system include alkali metal hydroxides, such as KOH, NaOH, LiOH; ammonium hydroxide; inorganic acids such as sulfuric, phosphoric, and the like; organic acids such as methanesulfonic acid; non-aqueous and aqueous solutions; alkali halide salts, such as the chlorides, bromides, and iodine types such as NaCl, NaBr, LiBr, and NaI; and acid halides such as HCl, HBr and Hl. The acid halides and alkali halide salts will produce for example chlorine, bromine, or iodine as a halide gas or as dissolved aqueous products from the anolyte compartment. Methanol or other hydrocarbon non-aqueous liquids can also be used, and would form some oxidized organic products from the anolyte. Selection of the anolyte would be determined by the process chemistry product and requirements for lowering the overall operating cell voltage. For example, the formation of bromine at the anode requires a significantly lower anode voltage potential than chlorine formation, and iodine is even lower than that of bromine. This allows for a significant power cost savings in the operation of both of the electrochemical units when bromine is generated in the anolyte. The formation of a halogen, such as bromine, in the anolyte may then be used in an external reaction to produce other compounds, such as reactions with alkanes to form bromoethane, which may then be converted to an alcohol, such as ethanol, or an alkene, such as ethylene, and the halogen acid byproduct from the reaction can be recycled back to the electrochemical cell anolyte.
  • Operation of the electrolyzer catholyte at a higher operating pressure may allow more carbon dioxide to dissolve in the aqueous electrolyte than at lower pressures (e.g., ambient pressures). Electrochemical cells may operate at pressures up to about 20 to 30 psig in multi-cell stack designs, although with modifications, they could operate at up to 100 psig. The electrolyzer anolyte may also be operated in the same pressure range to minimize the pressure differential on the membrane separating the two electrode compartments. Special electrochemical designs are required to operate electrochemical units at higher operating pressures up to about 60 to 100 atmospheres or greater, which is in the liquid CO2 and supercritical CO2 operating range.
  • In a particular implementation, a portion of the catholyte recycle stream may be separately pressurized using a flow restriction with backpressure or using a pump, with CO2 injection, such that the pressurized stream is then injected into the catholyte compartment of the electrolyzer. Such a configuration may increase the amount of dissolved CO2 in the aqueous solution to improve the conversion yield.
  • Catholyte and anolyte operating temperatures preferably range from −10 to 95° C., more preferably 5 to 60° C. The minimum operating temperature will be limited to the electrolytes used and their freezing points. In general, the lower the temperature, the higher the solubility of CO2 in the aqueous solution phase of the electrolyte, and would help in obtaining higher conversion and current efficiencies. A consideration for lower operating temperatures is that the operating electrolyzer cell voltages may be higher, so an optimization may be required to produce the chemicals at the lowest operating cost.
  • The electrochemical cell design may include a zero gap, flow-through design with a recirculating catholyte electrolyte with various high surface area cathode materials. Other designs include: flooded co-current packed and trickle bed designs with the various high surface area cathode materials, bipolar stack cell designs, and high pressure cell designs.
  • Anodes for use in the electrochemical system may depend on various system conditions. For acidic anolytes and to oxidize water to generate oxygen and hydrogen ions, the anode may include a coating, with preferred electrocatalytic coatings including precious metal oxides, such as ruthenium and iridium oxides, as well as platinum, rhodium, and gold and their combinations as metals and oxides deposited on valve metal substrates, such as titanium, tantalum, zirconium, and niobium. For other anolytes, such as alkaline or hydroxide electrolytes, the anode made include carbon, cobalt oxides, stainless steels, nickel, and their alloys and combinations which may be stable as anodes suitable under alkaline conditions.
  • As described herein, the electrochemical system may employ a membrane positioned between the anode compartment and the cathode compartment. Cation ion exchange type membranes are preferred, especially those that have a high rejection efficiency to anions, for example perfluorinated sulfonic acid based ion exchange membranes such as DuPont Nafion® brand unreinforced types N117 and N120 series, more preferred PTFE fiber reinforced N324 and N424 types, and similar related membranes manufactured by Japanese companies under the supplier trade names such as Flemion®. Other multi-layer perfluorinated ion exchange membranes used in the chlor alkali industry have a bilayer construction of a sulfonic acid based membrane layer bonded to a carboxylic acid based membrane layer, which efficiently operates with an anolyte and catholyte above a pH of about 2 or higher. These membranes have a much higher anion rejection efficiency. These are sold by DuPont under their Nafion® trademark as the N900 series, such as the N90209, N966, N982, and the 2000 series, such as the N2010, N2020, and N2030 and all of their types and subtypes. Hydrocarbon based membranes, which are made from various cation ion exchange materials can also be used if the anion rejection is not as critical, such as those sold by Sybron under their trade name Ionac®, AGC Engineering (Asahi Glass) under their Selemion® trade name, and Tokuyama Soda, among others available on the market.
  • Example Electrolyzer Design
  • The electrolyzer design used in laboratory examples may incorporate various thickness high surface area cathode structures using added spacer frames and also provide the physical contact pressure for the electrical contact to the cathode current conductor backplate.
  • An electrochemical bench scale cell with an electrode projected area of about 108 cm2 was used for much of the bench scale test examples. The electrochemical cell was constructed consisting of two electrode compartments machined from 1.0 inch (2.54 cm) thick natural polypropylene. The outside dimensions of the anode and cathode compartments were 8 inches (20.32 cm) by 5 inches (12.70 cm) with an internal machined recess of 0.375 inches (0.9525 cm) deep and 3.0 inches (7.62 cm) wide by 6 inches (15.24 cm) tall with a flat gasket sealing area face being 1.0 inches (2.52 cm) wide. Two holes were drilled equispaced in the recess area to accept two electrode conductor posts that pass though the compartment thickness, and having two 0.25 inch (0.635 cm) drilled and tapped holes to accept a plastic fitting that passes through 0.25 inch (0.635 cm) conductor posts and seals around it to not allow liquids from the electrode compartment to escape to the outside. The electrode frames were drilled with an upper and lower flow distribution hole with 0.25 inch pipe threaded holes with plastic fittings installed to the outside of the cell frames at the top and bottom of the cells to provide flow into and out of the cell frame, and twelve 0.125 inch (0.3175 cm) holes were drilled through a 45 degree bevel at the edge of the recess area to the upper and lower flow distribution holes to provide an equal flow distribution across the surface of the flat electrodes and through the thickness of the high surface area electrodes of the compartments.
  • For the anode compartment cell frames, an anode with a thickness of 0.060 inch (0.1524 cm) and 2.875 inch (7.3025 cm) width and 5.875 inch (14.9225 cm) length with two 0.25 inch (0.635 cm) titanium diameter conductor posts welded on the backside were fitted through the two holes drilled in the electrode compartment recess area. The positioning depth of the anode in the recess depth was adjusted by adding plastic spacers behind the anode, and the edges of the anode to the cell frame recess were sealed using a medical grade epoxy. The electrocatalyst coating on the anode was a Water Star WS-32, an iridium oxide based coating on a 0.060 inch (0.1524 cm) thick titanium substrate, suitable for oxygen evolution in acids. In addition, the anode compartment also employed an anode folded screen (folded three times) that was placed between the anode and the membrane, which was a 0.010 inch (0.0254 cm) thick titanium expanded metal material from DeNora North America (EC626), with an iridium oxide based oxygen evolution coating, and used to provide a zero gap anode configuration (anode in contact with membrane), and to provide pressure against the membrane from the anode side which also had contact pressure from the cathode side.
  • For the cathode compartment cell frames, 316L stainless steel cathodes with a thickness of 0.080 inch (0.2032 cm) and 2.875 inch (7.3025 cm) width and 5.875 inch (14.9225 cm) length with two 0.25 inch (0.635 cm) diameter 316L SS conductor posts welded on the backside were fitted through the two holes drilled in the electrode compartment recess area. The positioning depth of the cathode in the recess depth was adjusted by adding plastic spacers behind the cathode, and the edges of the cathode to the cell frame recess were sealed using a fast cure medical grade epoxy.
  • A copper bar was connected between the two anode posts and the cathode posts to distribute the current to the electrode back plate. The cell was assembled and compressed using 0.25 inch (0.635 cm) bolts and nuts with a compression force of about 60 in-lbs force. Neoprene elastomer is gaskets (0.0625 inch (0.159 cm) thick) were used as the sealing gaskets between the cell frames, frame spacers, and the membranes.
  • Example 1
  • The above cell was assembled with a 0.010 inch (0.0254 cm) thickness indium foil mounted on the 316L SS back conductor plate using a conductive silver epoxy. A multi-layered high surface area cathode, comprising an electrolessly applied indium layer of about 1 micron thickness that was deposited on a previously applied layer of electroless tin with a thickness of about 25 micron thickness onto a woven copper fiber substrate. The base copper fiber structure was a copper woven mesh obtained from an on-line internet supplier, PestMall.com (Anteater Pest Control Inc.). The copper fiber dimensions in the woven mesh had a thickness of 0.0025 inches (0.00635 cm) and width of 0.010 inches (0.0254 cm). The prepared high surface area cathode material was folded into a pad that was 1.25 inches (3.175 cm) thick and 6 inches (15.24 cm) high and 3 inches (7.62 cm) wide, which filled the cathode compartment dimensions and exceeded the adjusted compartment thickness (adding spacer) which was 0.875 inches (2.225 cm) by about 0.25 inches (0.635 cm). The prepared cathode had a calculated surface area of about 3,171 cm2, for an area about 31 times the flat cathode plate area, with a 91% void volume, and specific surface area of 12.3 cm2/cm3. The cathode pad was compressible, and provided the spring force to make contact with the cathode plate and the membrane. Two layers of a very thin (0.002 inches thick) plastic screen with large 0.125 inch (0.3175 cm) holes were installed between the cathode mesh and the Nafion® 324 membrane. Neoprene gaskets (0.0625 inch (0.159 cm) thick) were used as the sealing gaskets between the cell frames and the membranes. The electrocatalyst coating on the anode in the anolyte compartment was a Water Star WS-32, an iridium oxide based coating, suitable for oxygen evolution in acids. In addition, the anode compartment also employed a three-folded screen that was placed between the anode and the membrane, which was a 0.010 inch (0.0254 cm) thick titanium expanded metal material from DeNora North America (EC626), with an iridium oxide based oxygen evolution coating, and used to provide a zero gap anode configuration (anode in contact with membrane), and to provide pressure against the membrane from the anode side which also had contact pressure from the cathode side.
  • The cell assembly was tightened down with stainless steel bolts, and mounted into the cell station, which has the same configuration as shown in FIG. 1 with a catholyte disengager, a centrifugal catholyte circulation pump, inlet cell pH and outlet cell pH sensors, a temperature sensor on the outlet solution stream. A 5 micron stainless steel frit filter was used to sparge carbon dioxide into the solution into the catholyte disengager volume to provide dissolved carbon dioxide into the recirculation stream back to the catholyte cell inlet.
  • The anolyte used was a dilute 5% by volume sulfuric acid solution, made from reagent grade 98% sulfuric acid and deionized water.
  • In this test run, the system was operated with a catholyte composition containing 0.4 molar potassium sulfate aqueous with 2 gm/L of potassium bicarbonate added, which was sparged with carbon dioxide to an ending pH of 6.60.
  • Operating Conditions:
  • Batch Catholyte Recirculation Run Anolyte Solution: 0.92 M H2SO4 Catholyte Solution: 0.4 M K2SO4, 0.14 mM KHCO3
  • Catholyte flow rate: 2.5 LPM
    Catholyte flow velocity: 0.08 ft/sec
    Applied cell current: 6 amps (6,000 mA)
    Catholyte pH range: 5.5-6.6, controlled by periodic additions of potassium bicarbonate to the catholyte solution recirculation loop. Catholyte pH declines with time, and is controlled by the addition of potassium bicarbonate.
  • Results:
  • Cell voltage range: 3.39-3.55 volts (slightly lower voltage when the catholyte pH drops)
    Run time: 6 hours
    Formate Faradaic yield: Steady between 32-35%, calculated taking samples periodically. See FIG. 7.
    Final formate concentration: 9,845 ppm
  • Example 2
  • The same cell as in Example 1 was used with the same cathode, which was only rinsed with water while in the electrochemical cell after the run was completed and then used for this run.
  • In this test run, the system was operated with a catholyte composition containing 0.375 molar potassium sulfate aqueous with 40 gm/L of potassium bicarbonate added, which was sparged with carbon dioxide to an ending pH of 7.05.
  • Operating Conditions:
  • Batch Catholyte Recirculation Run Anolyte Solution: 0.92 M H2SO4 Catholyte Solution: 0.4 M K2SO4, 0.4 M KHCO3
  • Catholyte flow rate: 2.5 LPM
    Catholyte flow velocity: 0.08 ft/sec
    Applied cell current: 6 amps (6,000 mA)
    Catholyte pH range: Dropping from 7.5 to 6.75 linearly with time during the run.
  • Results:
  • Cell voltage range: 3.40-3.45 volts
    Run time: 5.5 hours
    Formate Faradaic yield: Steady at 52% and slowly declining with time to 44% as the catholyte pH dropped. See FIG. 8.
    Final formate concentration: 13,078 ppm
  • Example 3
  • The same cell as in Examples 1 and 2 was used with the same cathode, which was only rinsed with water while in the electrochemical cell after the run was completed and then used for this run.
  • In this test run, the system was operated with a catholyte composition containing 0.200 molar potassium sulfate aqueous with 40 gm/L of potassium bicarbonate added, which was sparged with carbon dioxide to an ending pH of 7.10.
  • Operating Conditions:
  • Batch Catholyte Recirculation Run Anolyte Solution: 0.92 M H2SO4 Catholyte Solution: 0.2 M K2SO4, 0.4 M KHCO3
  • Catholyte flow rate: 2.5 LPM
    Catholyte flow velocity: 0.08 ft/sec
    Applied cell current: 9 amps (9,000 mA)
    Catholyte pH range: Dropping from 7.5 to 6.65 linearly with time during the run, and then additional solid KHCO3 was added to the catholyte loop in 10 gm increments at the 210, 252, and 290 minute time marks which brought the pH back up to about a pH of 7 for the last part of the run.
  • Results:
  • Cell voltage range: 3.98-3.80 volts
    Run time: 6.2 hours
    Formate Faradaic yield: 75% declining to 60% at a pH of 6.65, and then increasing to 75% upon the addition of solid potassium bicarbonate to the catholyte to the catholyte loop in 10 gm increments at the 210, 252, and 290 minute time marks and slowly declining down with time 68% as the catholyte pH dropped to 6.90. See FIG. 9.
    Final formate concentration: 31,809 ppm.
  • Example 4
  • The same cell as in Examples 1, 2, and 3 was used with the same cathode, which was only rinsed with water while in the electrochemical cell after the run was completed and then used for this run.
  • In this test run, the system was operated with a catholyte composition containing 1.40 molar potassium bicarbonate (120 gm/L KHCO3), which was sparged with carbon dioxide to an ending pH of 7.8.
  • Operating Conditions:
  • Batch Catholyte Recirculation Run Anolyte Solution: 0.92 M H2SO4 Catholyte Solution: 1.4 M KHCO3
  • Catholyte flow rate: 2.6 LPM
    Catholyte flow velocity: 0.09 ft/sec
    Applied cell current: 11 amps (11,000 mA)
    Catholyte pH range: Dropping from around 7.8 linearly with time during the run to a final pH of 7.48
  • Results:
  • Cell voltage range: 3.98-3.82 volts
    Run time: 6 hours
    Formate Faradaic yield: 63% and settling down to about 54-55%. See FIG. 10.
    Final formate concentration: 29,987 ppm.
  • Prophetic Example 5
  • This example contemplates separation of product potassium formate from potassium carbonate/bicarbonate supporting electrolyte by membrane nano-filtration (NF) (FIG. 10). The test would involve two commercial NF membranes. The feed solution would comprise 1.2M KHCO3+0.6M K-formate and its pH would be adjusted to 7, 9, and 11 for three separate runs (for each membrane).
  • All NF tests would be performed in GE-Osmonic Sepa permeator (active membrane area of 0.0137 m2) at applied pressure of 40 bar (580 psig) and 50° C. During each run 3 liters of feed solution would be passed through and the permeate would be collected into a measuring cylinder (to determine volume) and the elapsed time recorded. The permeate would later be analyzed for total carbonate (HCO3 +CO3 2−) and formate. From such data, the permeability (in L/m2 h bar) and solute rejections (in %) would be calculated as follows:
  • Permeability = volume collected ( L ) membrane area ( m 2 ) × elapsed time ( h ) % Rejection = [ S ] Feed - [ S ] Permeate [ S ] Feed × 100
  • Where [S] denotes molar concentration of solute that could be either formate or total carbonate.
  • Expected results are summarized below:
  • GE-Desal DK Membrane
  • % Rejection
    Total Permeabiility
    Feed pH carbonate Formate L/m2 h bar
    7 11.4 2.2 1.72
    9 30.3 −9.7 1.07
    11 81.8 −46.3 0.36
  • Dow-Filmtec NF270 Membrane
  • % Rejection
    Total Permeabiility
    Feed pH carbonate Formate L/m2 h bar
    7 11.0 2.6 1.91
    9 29.5 −5.4 1.20
    11 80.1 −43.8 0.44
  • Prophetic Example 6
  • A single permeation test could be performed with DK membrane, using a formate-enriched Feed solution comprising 1.2M KHCO3+1.2M K-formate. The test could be done at pH 11 and all other conditions would be as in the above Example 1.
  • Such a test would likely give 79.9% and −33.8% rejection for total carbonate and formate, respectively. The permeability would be 0.32 L/m2 h bar.
  • Example 7
  • The same cell as in Examples 1, 2, and 3 was used, except for using 701 gm of tin shot (0.3-0.6 mm diameter) media with an electroless plated indium coating as the cathode. The cathode compartment thickness was 0.875 inches.
  • In this test run, the system was operated with a catholyte composition containing 1.40 molar potassium bicarbonate (120 gm/L KHCO3), which was sparged with carbon dioxide to an ending pH of 8.0
  • The cell was operated in a batch condition with no overflow for the first 7.3 hrs, and then a 1.40 molar potassium bicarbonate feed was introduced into the catholyte at a rate of about 1.4 mL/min, with the overflow collected and measured, and a sample of the loop was collected for formate concentration analysis.
  • Operating Conditions:
  • Batch Catholyte Recirculation Run Anolyte Solution: 0.92 M H2SO4 Catholyte Solution: 1.4 M KHCO3
  • Catholyte flow rate: 3.2 LPM
    Applied cell current: 6 amps (6,000 mA)
    Catholyte pH range: Dropping slowly from around a pH of 8 linearly with time during the run to a final pH of 7.50
  • Results:
  • Cell voltage range: 3.98-3.82 volts
    Run time Batch mode: 7.3 hours
    Feed and product overflow: 7.3 hours to end of run at 47 hours.
  • The formate Faradaic efficiency was between 42% and 52% during the batch run period where the formate concentration went up to 10,490 ppm. During the feed and overflow period, the periodic calculated efficiencies varied between 32% and 49%. The average conversion efficiency was about 44%. The formate concentration varied between 10,490 and 48,000 ppm during the feed and overflow period. The cell voltage began at around 4.05 volts, ending up at 3.80 volts.
  • Example 8
  • Electrolyses were performed using a 3-compartment glass cell of roughly 80 mL total volume. The cell was constructed to be gas tight with Teflon bushings. The compartments were separated by 2 glass frits. A 3-electrode assembly was employed. One compartment housed the working electrode and the reference electrode (Accumet silver/silver chloride) which contained the aqueous electrolyte and catalyst as stated. The center compartment also contained the electrolyte and catalyst solution as stated. The third compartment was filled with 0.5 molar K2SO4 aqueous electrolyte solution sparged with CO2 with a pH of about 4.5 and housed the counter electrode (TELPRO (Stafford, Tex.)—Mixed Metal Oxide Electrode). The working electrode compartment was purged with carbon dioxide during the experiment. The solutions were measured by ion chromatography for formic acid, analyzing the solution before (a blank) and after electrolysis. The tests were conducted under potentiometric conditions using a 6 channel Arbin Instruments MSTAT, operating at −1.46 or −1.90 volts vs. an SCE reference electrode for about 1.5 hrs.
  • Exper-
    iment Formate Applied Cur-
    Cathode Desig- Produced Formate Potential rent Time
    Evaluated nation (ppm) Yield % (volts) (ma) (hrs)
    Electroplated DK80 1,818 75.8 −1.9 50 1.5
    indium on
    tin foil
    Electroplated DK82 1,956 64.0 −1.9 58.5 1.5
    indium on
    tin foil
    Untreated DK80 1,260 54.3 −1.9 44.5 1.5
    tin foil
    Electroplated DK83 1,887 31.7 −1.9 123 1.5
    indium on
    copper foil
    Tin foil DK80 604 18.0 −1.9 54.8 1.5
    (untreated)
    Copper DK79 1,813 30.6 −1.46 97.9 1.5
    screen with
    electroless
    indium
    coating
    Copper DK78 1,387 43.9 −1.46 63.6 1.5
    screen with
    electroless
    indium
    annealed at
    200° C.
  • Example 9
  • The same cell as in Examples 1, 2, and 3 was used, except for using 890.5 gm of tin shot (3 mm diameter) media and with a tin foil coating as the cathode. The cathode compartment thickness was 1.25 inches and the system was operated in a batch mode with no feed input. Carbon dioxide was sparged to saturate the solution in the catholyte disengager.
  • Packed Tin Bed Cathode Detail:
  • Weight: 890.5 gm tin shot
    Tin shot: 3 mm average size
    Total compartment volume: 369 cm3
    Calculated tin bead surface area: 4,498 cm2
    Calculated packed bed cathode specific surface area: 12.2 cm2/cm3
    Calculated packed bed void volume: 34.6%
  • In this test run, the system was operated with a catholyte composition containing 1.40 molar potassium bicarbonate (120 gm/L KHCO3), which was sparged with CO2 to an ending pH of about 8.0
  • The cell was operated in a batch condition with no overflow and a sample of the catholyte loop was collected for formate concentration analysis periodically.
  • Operating Conditions:
    • Batch Catholyte Recirculation Run
    • Anolyte Solution: 0.92 M H2SO4
    • Catholyte Solution: 1.4 M KHCO3
    • Catholyte flow rate: 3.0 LPM (upflow)
    • Catholyte flow velocity: 0.068 ft/sec
    • Applied cell current: 6 amps (6,000 mA)
    • Catholyte pH range: Increasing slowly from around a pH of 7.62 linearly with time during the run to a final pH of 7.73
  • Results:
  • Cell voltage range: Started at 3.84 volts, and slowly declined to 3.42 volts
    Run time: Batch mode, 19 hours
  • The formate Faradaic efficiency started at about 65% and declined after 10 hours to 36% and to about 18.3% after 19 hours. The final formate concentration ended up at 20,500 ppm at the end of the 19 hour run. See FIGS. 11 and 12.
  • Example 10
  • The same cell as in Examples 1, 2, and 3 was used, except for using 805 gm of indium coated tin shot (3 mm diameter) media and with a 0.010 inch (0.0254 cm) thickness indium foil mounted on the 316L SS back conductor plate using a conductive silver epoxy as the cathode. The cathode compartment thickness was 1.25 inches and the system was operated in a batch mode with no feed input. Carbon dioxide was sparged to saturate the solution in the catholyte disengager. The tin shot was electrolessly plated with indium in the same method as used in Examples 1-4 on the tin-coated copper mesh. The indium coating was estimated to be about 0.5-1.0 microns in thickness.
  • Indium-Coated Tin Shot Packed Bed Cathode Detail:
  • Weight: 890.5 gm, indium coating on tin shot
    Indium coated tin shot: 3 mm average size
    Total compartment volume: 369 cm3
    Calculated tin bead surface area: 4498 cm2
    Packed bed cathode specific surface area: 12.2 cm2/cm3
    Packed bed void volume: 34.6%
  • In this test run, the system was operated with a catholyte composition containing 1.40 molar potassium bicarbonate (120 gm/L KHCO3), which was sparged with CO2 to an ending pH of about 8.0
  • The cell was operated in a batch condition with no overflow and a sample of the catholyte loop was collected for formate concentration analysis periodically.
  • Operating Conditions:
    • Batch Catholyte Recirculation Run
    • Anolyte Solution: 0.92 M H2SO4
    • Catholyte Solution: 1.4 M KHCO3
    • Catholyte flow rate: 3.0 LPM (upflow)
    • Catholyte flow velocity: 0.068 ft/sec
    • Applied cell current: 6 amps (6,000 mA)
    • Catholyte pH range: Decreased slowly from around a pH of 7.86 linearly with time during the run to a final pH of 5.51
  • Results:
  • Cell voltage range: Started at 3.68 volts, and slowly declined to 3.18 volts
    Run time Batch mode, 24 hours
  • The formate Faradaic efficiency started at about 100% and varied between 60% to 85%, ending at about 60% after 24 hours. The final formate concentration ended up at about 60,000 ppm at the end of the 24 hour run. Dilution error of the samples at the high formate concentrations may have provided the variability seen in the yield numbers. See FIGS. 13 and 14.
  • Example 11
  • The same cell as in Examples 1, 2, and 3 was used with a newly prepared indium on tin electrocatalyst coating on a copper mesh cathode. The prepared cathode had calculated surface areas of about 3,171 cm2, for an area about 31 times the flat cathode plate area, with a 91% void volume, and specific surface area of 12.3 cm2/cm3.
  • In this test run, the system was operated with a catholyte composition containing 1.40 M potassium bicarbonate (120 gm/L KHCO3), which was sparged with CO2 to an ending pH of 7.8 before being used.
  • The cells were operated in a recirculating batch mode for the first 8 hours of operation to get the catholyte formate ion concentration up to about 20,000 ppm, and then a fresh feed of 1.4 M potassium bicarbonate was metered into the catholyte at a feed rate of about 1.2 mL/min. The overflow volume was collected and volume measured, and the overflow and catholyte loop sample were sampled and analyzed for formate by ion chromatography.
  • Operating Conditions:
  • Cathode: Electroless indium on tin on a copper mesh substrate Continuous Feed with Catholyte Recirculation Run—11.5 days
  • Anolyte Solution: 0.92 M H2SO4 Catholyte Solution: 1.4 M KHCO3
  • Catholyte flow rate: 3.2 LPM
    Catholyte flow velocity: 0.09 ft/sec
    Applied cell current: 6 amps (6,000 mA)
  • Results:
    • Cell voltage versus time: FIG. 15 illustrates results of cell voltage versus time, displaying a stable operating voltage of about 3.45 volts over the 11.5 days after the initial start-up.
    • Continuous Run time: 11.5 days
    • Formate Concentration Versus Time: FIG. 16 shows results of the formate concentration versus time.
    • FIG. 17 shows a scanning electron microscope (SEM) image of the electroless indium coating on tin-plated copper fiber cathode after 11.5 days of continuous electrolysis. (FIG. 18 shows an SEM image of an example electroless indium coating on a treated carbon fiber material, which was not used in Example 11.)
    • Formate Faradaic yield: FIG. 19 illustrates the calculated formate current efficiency versus time measuring the formate yield from the collected samples.
    • Final formate concentration: About 28,000 ppm.
    • Catholyte pH: FIG. 20 illustrates the catholyte pH change over the 11.5 days, which slowly declined from a pH of 7.8 to a pH value of 7.5. The feed rate was not changed during the run, but could have been slowly increased or decreased to maintain a constant catholyte pH in any optimum operating pH range.
    Example 12
  • The same cell as in Examples 1, 2, and 3 was used with a newly prepared indium on tin electrocatalyst coating on a copper mesh cathode. The prepared cathode had calculated surface areas of about 3,171 cm2, for an area about 31 times the flat cathode plate area, with a 91% void volume, and specific surface area of 12.3 cm2/cm3.
  • In this test run, the system was operated with a catholyte composition containing 1.40 M potassium bicarbonate (120 gm/L KHCO3), which was sparged with CO2 to an ending pH of 7.8 before being used.
  • The cells were operated in a recirculating batch mode for the first 8 hours of operation to get the catholyte formate ion concentration up to about 20,000 ppm, and then a fresh feed of 1.4 M potassium bicarbonate was metered into the catholyte at a feed rate of about 1.2 mL/min. The overflow volume was collected and volume measured, and the overflow and catholyte loop sample were sampled and analyzed for formate by ion chromatography.
  • Operating Conditions:
  • Cathode: Electroless indium on tin on a copper mesh substrate
    Continuous Feed with Catholyte Recirculation Run—21 days
  • Anolyte Solution: 0.92 M H2SO4 Catholyte Solution: 1.4 M KHCO3
  • Catholyte flow rate: 3.2 LPM
    Catholyte flow velocity: 0.09 ft/sec
  • Applied cell current: 6 amps (6,000 mA)
  • Results:
    • Cell voltage versus time: The cell showed a higher operating voltage of about 4.40 volts, higher than all of our other cells, because of an inadequate electrical contact pressure of the cathode against the indium foil conductor back plate. The cell maintained operation for an extended run.
    • Continuous Run time: 21 days
  • Formate Faradaic yield: FIG. 21 illustrates calculated formate current efficiency versus time measuring the formate yield from the collected samples. The formate Faradaic current efficiency declined down into the 20% range after 16 days.
  • Formate Concentration Versus Time: FIG. 22 illustrates results of the formate concentration versus time. On day 21, 0.5 gm of indium (III) carbonate was added to the catholyte while the cell was still operating at the 6 ampere operating rate. The formate concentration in the catholyte operating loop was 11,330 ppm before the indium addition, which increased to 13,400 ppm after 8 hours, and increased to 14,100 ppm after 16 hours when the unit was shut down after 21 days of operation.
  • Catholyte pH: FIG. 23 illustrates the catholyte pH change over the continuous operation period, which operated in the 7.6 to 7.7 pH range except for an outlier data point near day 16 when the feed pump had stopped pumping. The feed rate was not changed during the run, but could have been increased or decreased to maintain a constant pH operation in an optimum range.
  • It is believed that the present disclosure and many of its attendant advantages will be understood by the foregoing description, and it will be apparent that various changes may be made in the form, construction and arrangement of the components thereof without departing from the scope and spirit of the disclosure or without sacrificing all of its material advantages. The form herein before described being merely an explanatory embodiment thereof, it is the intention of the following claims to encompass and include such changes.

Claims (30)

What is claimed is:
1. A system for electrochemical reduction of carbon dioxide into products, comprising:
a first electrochemical cell including:
a cathode compartment containing a high surface area cathode and a bicarbonate-based catholyte saturated with carbon dioxide, the high surface area cathode including an indium coating and having a void volume of between about 30% to 98%; and
an anode compartment containing an anode and an acidic anolyte,
wherein the electrochemical cell is configured to produce a product upon application of an electrical potential between the anode and the cathode.
2. The system of claim 1 further comprising:
a cation ion exchange membrane positioned between the cathode compartment and the anode compartment.
3. The system of claim 1, wherein the high surface area cathode includes indium deposited on tin.
4. The system of claim 3, wherein the high surface area cathode further includes at least one of a copper substrate or a conductive substrate, the tin layered on the at least one of the copper substrate or the conductive substrate.
5. The system of claim 1, wherein the anode comprises an electrocatalytic coating including at least one of ruthenium oxide, iridium oxide, platinum, a platinum oxide, gold, or a gold oxide.
6. The system of claim 1, wherein the product of the first electrochemical cell includes an alkali metal formate.
7. The system of claim 1, wherein the cathode compartment further contains a homogenous heterocyclic amine catalyst.
8. The system of claim 7, wherein the homogenous heterocyclic amine catalyst is selected from the group consisting of 4-hydroxy pyridine, adenine, a heterocyclic amine containing sulfur, a heterocyclic amine containing oxygen, an azole, a benzimidazole, a bipyridine, a furan, an imidazole, an imidazole related species with at least one five-member ring, an indole, a lutidine, a methylimidazole, an oxazole, a phenanthroline, a pterin, a pteridine, pyridine, a pyridine related species with at least one six-member ring, a pyrrole, a quinoline, or a thiazole, and mixtures thereof.
9. The system of claim 1, further comprising:
a first separator configured to receive an output from the anode compartment, wherein at least a portion of a product of the first separator is recycled to the anode compartment; and
a second separator configured to receive an output from the cathode compartment, wherein at least a portion of a product of the second separator is recycled to the cathode compartment.
10. The system of claim 1, further comprising:
a second electrochemical cell including:
a catholyte compartment comprising a cathode;
an anolyte compartment comprising an anode; and
an ion exchange compartment positioned between the catholyte compartment and the anolyte compartment, the ion exchange compartment including an input port configured to receive the product from the electrochemical cell,
wherein the second electrochemical cell is configured to produce a second product upon application of an electrical potential between the anode and the cathode.
11. The system of claim 10, wherein the second product of the second electrochemical cell includes formic acid.
12. The system of claim 10, wherein the bicarbonate-based catholyte of the first electrochemical cell includes potassium bicarbonate, wherein the product of the first electrochemical cell includes potassium formate, and wherein the second product of the second electrochemical cell includes formic acid.
13. The system of claim 10, further comprising:
a third separator configured to receive an output from the anolyte compartment of the second electrochemical cell, wherein at least a portion of a product of the third separator is recycled to the anolyte compartment of the second electrochemical cell; and
a fourth separator configured to receive an output from the catholyte compartment of the second electrochemical cell, wherein at least a portion of a product of the fourth separator is recycled to the catholyte compartment of the second electrochemical cell.
14. The system of claim 13, further comprising:
a catholyte recycle reactor, the catholyte recycle reactor including an input port configured to receive at least a portion of the product from the fourth separator, wherein at least a portion of a product of the catholyte recycle reactor is recycled to the cathode compartment of the first electrochemical cell.
15. The system of claim 14, further comprising:
a carbon dioxide distribution module, the carbon dioxide distribution module configured to receive carbon dioxide from at least a portion of the product of one or more of the first separator, the second separator, the third separator, and the fourth separator, wherein the carbon dioxide distribution module is configured to distribute carbon dioxide to one or more of the cathode compartment of the first electrochemical cell and the catholyte recycle reactor.
16. The system of claim 10, wherein the second electrochemical cell includes a plurality of bipolar membranes.
17. The system of claim 10, further comprising:
a nano-filtration system coupled between the electrochemical cell and the second electrochemical cell, the nano-filtration system configured to receive the product from the first electrochemical cell and to separate at least one of a carbonate or a bicarbonate from an alkali metal formate, the nano-filtration system configured to send the alkali metal formate to the ion exchange compartment of the second electrochemical cell.
18. A system for electrochemical reduction of carbon dioxide into products, comprising:
an electrolyzer system configured for the reduction of carbon dioxide to an alkali metal formate, the electrolyzer system including:
an electrolyzer, comprising:
a first compartment containing an anolyte and an anode;
a second compartment containing a catholyte and a high surface area cathode, the catholyte including an alkali metal bicarbonate solution saturated with carbon dioxide, the high surface area cathode including an indium coating on tin and having a void volume of between about 30% to 98%, the high surface area cathode configured to reduce the carbon dioxide to the alkali metal formate;
a cation exchange membrane positioned between the first compartment and the second compartment;
an anolyte recycle loop configured to recirculate at least a portion of the anolyte;
a catholyte recycle loop configured to recirculate a least a portion of the catholyte;
an electrochemical acidification system configured to acidify the alkali metal formate to formic acid, the electrochemical acidification system including:
an electrochemical acidification unit including:
a catholyte compartment comprising a cathode;
an anolyte compartment comprising an anode; and
an ion exchange compartment positioned between the catholyte compartment and the anolyte compartment, the ion exchange compartment including an input port configured to receive the alkali metal formate from the electrolyzer,
wherein the electrochemical acidification unit is configured to produce formic acid upon application of an electrical potential between the anode and cathode of electrochemical acidification unit, and wherein said catholyte compartment is configured to produce an alkali metal hydroxide;
an alkali metal recycle system configured to receive the alkali metal hydroxide, and at least one of at least a portion of carbon dioxide generated from the electrochemical acidification system or at least a portion of residual carbon dioxide from the electrolyzer system, the alkali metal recycle system configured to generate at least a portion of the alkali metal bicarbonate solution fed to the second compartment of the electrolyzer.
19. A high surface area electrode, comprising:
a substrate including at least one of a metal or carbon, the substrate having a void volume of between about 30% to 98%; and
an electrocatalyst coating disposed on the surface of the electrode, the electrocatalyst coating covering about 5% to 100% of the electrode surface area, the electrocatalyst coating including indium in an amount of about 5% to 99% by weight.
20. The high surface area electrode of claim 19, wherein the substrate includes copper.
21. The high surface area electrode of claim 20, further including:
a tin coating on the copper substrate.
22. The high surface area electrode of claim 21, wherein the indium is coated on the tin coating.
23. The high surface area electrode of claim 19, wherein the electrocatalyst includes indium as a metal alloy.
24. The high surface area electrode of claim 23, wherein the metal alloy includes indium as an alloy with one or more of Sn, Pb, Hg, Tl, Bi, Cu, and Cd, and alloy mixtures thereof.
25. The high surface area electrode of claim 19, wherein the electrocatalyst coating further includes one or more of Au, Ag, Zn, Pb, and Pd in an amount of about 5% to 99% by weight.
26. The high surface area electrode of claim 19, wherein the electrocatalyst coating further includes an oxide of one of or more of Au, Ag, Bi, Cu, Cd, Pb, Pd, Hg, Sn, Tl, Zn, and mixtures thereof.
27. The high surface area electrode of claim 19, wherein the electrocatalyst coating is disposed as a single layer on the substrate.
28. The high surface area electrode of claim 19, wherein the electrocatalyst coating is disposed as a plurality of layers on the substrate.
29. The high surface area electrode of claim 28, wherein the plurality of layers includes at least a first layer deposited on a second layer; the first layer including indium, and the second layer including at least one of Au, Ag, Bi, Cu, Cd, Pb, Pd, Hg, Sn, Tl, Zn, and mixtures thereof.
30. The high surface area electrode of claim 19, wherein the substrate comprises a specific surface area of about 2 cm2/cm3.
US13/724,988 2012-07-26 2012-12-21 System and High Surface Area Electrodes for the Electrochemical Reduction of Carbon Dioxide Abandoned US20130105304A1 (en)

Priority Applications (5)

Application Number Priority Date Filing Date Title
US13/724,988 US20130105304A1 (en) 2012-07-26 2012-12-21 System and High Surface Area Electrodes for the Electrochemical Reduction of Carbon Dioxide
PCT/US2013/053558 WO2014042782A1 (en) 2012-09-14 2013-08-05 System and high surface area electrodes for the electrochemical reduction of carbon dioxide
US14/427,934 US9873951B2 (en) 2012-09-14 2013-09-16 High pressure electrochemical cell and process for the electrochemical reduction of carbon dioxide
PCT/US2013/060004 WO2014043651A2 (en) 2012-09-14 2013-09-16 High pressure electrochemical cell and process for the electrochemical reduction of carbon dioxide
US14/471,152 US10287696B2 (en) 2012-07-26 2014-08-28 Process and high surface area electrodes for the electrochemical reduction of carbon dioxide

Applications Claiming Priority (12)

Application Number Priority Date Filing Date Title
US201261675938P 2012-07-26 2012-07-26
US201261701237P 2012-09-14 2012-09-14
US201261703231P 2012-09-19 2012-09-19
US201261703158P 2012-09-19 2012-09-19
US201261703229P 2012-09-19 2012-09-19
US201261703232P 2012-09-19 2012-09-19
US201261703175P 2012-09-19 2012-09-19
US201261703234P 2012-09-19 2012-09-19
US201261703238P 2012-09-19 2012-09-19
US201261703187P 2012-09-19 2012-09-19
US201261720670P 2012-10-31 2012-10-31
US13/724,988 US20130105304A1 (en) 2012-07-26 2012-12-21 System and High Surface Area Electrodes for the Electrochemical Reduction of Carbon Dioxide

Related Child Applications (1)

Application Number Title Priority Date Filing Date
US13/724,885 Continuation US8858777B2 (en) 2012-07-26 2012-12-21 Process and high surface area electrodes for the electrochemical reduction of carbon dioxide

Publications (1)

Publication Number Publication Date
US20130105304A1 true US20130105304A1 (en) 2013-05-02

Family

ID=48171275

Family Applications (3)

Application Number Title Priority Date Filing Date
US13/724,988 Abandoned US20130105304A1 (en) 2012-07-26 2012-12-21 System and High Surface Area Electrodes for the Electrochemical Reduction of Carbon Dioxide
US13/724,885 Active US8858777B2 (en) 2012-07-26 2012-12-21 Process and high surface area electrodes for the electrochemical reduction of carbon dioxide
US14/471,152 Active 2034-05-29 US10287696B2 (en) 2012-07-26 2014-08-28 Process and high surface area electrodes for the electrochemical reduction of carbon dioxide

Family Applications After (2)

Application Number Title Priority Date Filing Date
US13/724,885 Active US8858777B2 (en) 2012-07-26 2012-12-21 Process and high surface area electrodes for the electrochemical reduction of carbon dioxide
US14/471,152 Active 2034-05-29 US10287696B2 (en) 2012-07-26 2014-08-28 Process and high surface area electrodes for the electrochemical reduction of carbon dioxide

Country Status (1)

Country Link
US (3) US20130105304A1 (en)

Cited By (88)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US20130180865A1 (en) * 2010-07-29 2013-07-18 Liquid Light, Inc. Reducing Carbon Dioxide to Products
US8641885B2 (en) 2012-07-26 2014-02-04 Liquid Light, Inc. Multiphase electrochemical reduction of CO2
US8647493B2 (en) 2012-07-26 2014-02-11 Liquid Light, Inc. Electrochemical co-production of chemicals employing the recycling of a hydrogen halide
US8658016B2 (en) 2011-07-06 2014-02-25 Liquid Light, Inc. Carbon dioxide capture and conversion to organic products
US8663447B2 (en) 2009-01-29 2014-03-04 Princeton University Conversion of carbon dioxide to organic products
US8721866B2 (en) 2010-03-19 2014-05-13 Liquid Light, Inc. Electrochemical production of synthesis gas from carbon dioxide
CN103952717A (en) * 2014-05-07 2014-07-30 北京化工大学 Photoelectrochemical decomposition water and organic synthesis coupled cascade reaction design method
US8845877B2 (en) 2010-03-19 2014-09-30 Liquid Light, Inc. Heterocycle catalyzed electrochemical process
US8845878B2 (en) 2010-07-29 2014-09-30 Liquid Light, Inc. Reducing carbon dioxide to products
US8858777B2 (en) 2012-07-26 2014-10-14 Liquid Light, Inc. Process and high surface area electrodes for the electrochemical reduction of carbon dioxide
US8961774B2 (en) 2010-11-30 2015-02-24 Liquid Light, Inc. Electrochemical production of butanol from carbon dioxide and water
WO2015077508A1 (en) * 2013-11-20 2015-05-28 University Of Florida Research Foundation, Inc. Carbon dioxide reduction over carbon-containing materials
US9085827B2 (en) 2012-07-26 2015-07-21 Liquid Light, Inc. Integrated process for producing carboxylic acids from carbon dioxide
US9090976B2 (en) 2010-12-30 2015-07-28 The Trustees Of Princeton University Advanced aromatic amine heterocyclic catalysts for carbon dioxide reduction
WO2015143560A1 (en) * 2014-03-25 2015-10-01 Colin Oloman Process for the conversion of carbon dioxide to formic acid
US9222179B2 (en) 2010-03-19 2015-12-29 Liquid Light, Inc. Purification of carbon dioxide from a mixture of gases
US9267212B2 (en) 2012-07-26 2016-02-23 Liquid Light, Inc. Method and system for production of oxalic acid and oxalic acid reduction products
WO2016030749A1 (en) * 2014-08-29 2016-03-03 King Abdullah University Of Science And Technology Electrodes, methods of making electrodes, and methods of using electrodes
WO2016054400A1 (en) * 2014-10-01 2016-04-07 Anne Co Materials and methods for the electrochemical reduction of carbon dioxide
US9309599B2 (en) 2010-11-30 2016-04-12 Liquid Light, Inc. Heterocycle catalyzed carbonylation and hydroformylation with carbon dioxide
US9370773B2 (en) 2010-07-04 2016-06-21 Dioxide Materials, Inc. Ion-conducting membranes
US20160222528A1 (en) * 2015-02-03 2016-08-04 Alstom Technology Ltd Method for electrochemical reduction of co2 in an electrochemical cell
DE102015209509A1 (en) * 2015-05-22 2016-11-24 Siemens Aktiengesellschaft Electrolysis system for electrochemical carbon dioxide utilization with proton donor unit and reduction process
US20160369415A1 (en) * 2010-07-04 2016-12-22 Dioxide Materials, Inc. Catalyst Layers And Electrolyzers
JP2017001013A (en) * 2015-06-04 2017-01-05 株式会社豊田中央研究所 Electrode catalyst for carbon dioxide reduction, electrode, device and catalyst fixing method
WO2017014635A1 (en) 2015-07-22 2017-01-26 Coval Energy Ventures B.V. Method and reactor for electrochemically reducing carbon dioxide
US9580824B2 (en) 2010-07-04 2017-02-28 Dioxide Materials, Inc. Ion-conducting membranes
JP2017057438A (en) * 2015-09-14 2017-03-23 株式会社東芝 Reduction electrode and method of manufacturing the same, and electrolytic apparatus
US9642253B2 (en) 2011-04-04 2017-05-02 University Of Florida Research Foundation, Inc. Nanotube dispersants and dispersant free nanotube films therefrom
US20170130342A1 (en) * 2014-11-28 2017-05-11 Kabushiki Kaisha Toshiba Electrochemical reaction device
WO2017118712A1 (en) * 2016-01-05 2017-07-13 Avantium Holding B.V. Method and system for electrochemical reduction of carbon dioxide employing a gas diffusion anode
US20170233881A1 (en) * 2012-04-12 2017-08-17 Dioxide Materials, Inc. Water Electrolyzers
US9742018B2 (en) 2010-12-17 2017-08-22 University Of Florida Research Foundation, Inc. Hydrogen oxidation and generation over carbon films
US9849450B2 (en) 2010-07-04 2017-12-26 Dioxide Materials, Inc. Ion-conducting membranes
US9873951B2 (en) 2012-09-14 2018-01-23 Avantium Knowledge Centre B.V. High pressure electrochemical cell and process for the electrochemical reduction of carbon dioxide
US20180030604A1 (en) * 2016-08-01 2018-02-01 Fujitsu Limited Carbon dioxide-reduction device
EP3157897A4 (en) * 2014-06-19 2018-03-21 Avantium Knowledge Centre B.V. Integrated process for co-production of carboxylic acids and halogen products from carbon dioxide
WO2018059839A1 (en) * 2016-09-27 2018-04-05 Siemens Aktiengesellschaft Method and device for the electrochemical utilization of carbon dioxide
US9943841B2 (en) 2012-04-12 2018-04-17 Dioxide Materials, Inc. Method of making an anion exchange membrane
US9957624B2 (en) * 2010-03-26 2018-05-01 Dioxide Materials, Inc. Electrochemical devices comprising novel catalyst mixtures
US20180127668A1 (en) * 2015-05-05 2018-05-10 Dioxide Materials, Inc. System And Process For The Production Of Renewable Fuels And Chemicals
US20180179649A1 (en) * 2015-07-03 2018-06-28 Siemens Aktiengesellschaft Reduction Method And Electrolysis System For Electrochemical Carbon Dioxide Utilization
US10023967B2 (en) 2010-03-26 2018-07-17 Dioxide Materials, Inc. Electrochemical devices employing novel catalyst mixtures
US10047446B2 (en) 2010-07-04 2018-08-14 Dioxide Materials, Inc. Method and system for electrochemical production of formic acid from carbon dioxide
US10115972B2 (en) 2009-04-30 2018-10-30 University Of Florida Research Foundation, Incorporated Single wall carbon nanotube based air cathodes
US20180312786A1 (en) * 2017-04-26 2018-11-01 Kunshan Nano New Material Technology Co.,Ltd Nano super ion water and preparation method of the same
CN108796548A (en) * 2018-07-05 2018-11-13 哈尔滨工业大学 The method that electro-catalysis reduction carbon dioxide prepares formic acid and acetic acid in heteropolyacid anions-acetonitrile-water ternary electrolyte system
US10147974B2 (en) 2017-05-01 2018-12-04 Dioxide Materials, Inc Battery separator membrane and battery employing same
US10173169B2 (en) 2010-03-26 2019-01-08 Dioxide Materials, Inc Devices for electrocatalytic conversion of carbon dioxide
WO2019025092A1 (en) * 2017-08-03 2019-02-07 Siemens Aktiengesellschaft Device and method for the electrochemical utilisation of carbon dioxide
CN109642332A (en) * 2016-08-29 2019-04-16 二氧化碳材料公司 System and method for producing recyclable fuel and chemicals
JP2019510884A (en) * 2016-04-04 2019-04-18 ダイオキサイド マテリアルズ,インコーポレイティド Catalyst layer and electrolytic cell
CN109675586A (en) * 2018-12-26 2019-04-26 厦门大学 The catalyst and preparation method thereof of electroreduction carbon dioxide formic acid
JP2019513895A (en) * 2016-04-04 2019-05-30 ダイオキサイド マテリアルズ,インコーポレイティド Water electrolytic cell
US10329676B2 (en) 2012-07-26 2019-06-25 Avantium Knowledge Centre B.V. Method and system for electrochemical reduction of carbon dioxide employing a gas diffusion electrode
JP2019519668A (en) * 2016-04-04 2019-07-11 ダイオキサイド マテリアルズ,インコーポレイティド Ion conductive membrane
WO2019141827A1 (en) * 2018-01-18 2019-07-25 Avantium Knowledge Centre B.V. Catalyst system for catalyzed electrochemical reactions and preparation thereof, applications and uses thereof
CN110117794A (en) * 2019-05-21 2019-08-13 盐城工学院 A kind of electroreduction CO2The three Room type electrolytic cell devices and its electrolytic method of formates processed
US10396329B2 (en) 2017-05-01 2019-08-27 Dioxide Materials, Inc. Battery separator membrane and battery employing same
EP3473750A4 (en) * 2016-03-29 2020-04-22 Techwin Co., Ltd. Electrolysis system and electrolysis method using same
US10647652B2 (en) 2013-02-24 2020-05-12 Dioxide Materials, Inc. Process for the sustainable production of acrylic acid
US10648091B2 (en) 2016-05-03 2020-05-12 Opus 12 Inc. Reactor with advanced architecture for the electrochemical reaction of CO2, CO, and other chemical compounds
WO2020112919A1 (en) * 2018-11-28 2020-06-04 Opus 12, Inc. Electrolyzer and method of use
CN111304672A (en) * 2020-03-18 2020-06-19 大连理工大学 H-shaped fixed bed carbon dioxide reduction electrolytic cell and application
US10724142B2 (en) 2014-10-21 2020-07-28 Dioxide Materials, Inc. Water electrolyzers employing anion exchange membranes
US10774431B2 (en) 2014-10-21 2020-09-15 Dioxide Materials, Inc. Ion-conducting membranes
WO2020240218A1 (en) 2019-05-25 2020-12-03 Szegedi Tudományegyetem Modular electrolyzer cell and process to convert carbon dioxide to gaseous products at elevated pressure and with high conversion rate
JP2021046575A (en) * 2019-09-17 2021-03-25 株式会社東芝 Carbon dioxide electrolytic device and carbon dioxide electrolytic method
US10975481B2 (en) * 2012-12-06 2021-04-13 Tsinghua University Cathode catalyst, cathode material using the same, and reactor using the same
US10975477B2 (en) * 2017-10-02 2021-04-13 Battelle Energy Alliance, Llc Methods and systems for the electrochemical reduction of carbon dioxide using switchable polarity materials
US10975480B2 (en) 2015-02-03 2021-04-13 Dioxide Materials, Inc. Electrocatalytic process for carbon dioxide conversion
US11000027B2 (en) * 2017-10-17 2021-05-11 Geka Solutions Pty Ltd Pest control system
WO2021122323A1 (en) 2019-12-20 2021-06-24 Avantium Knowledge Centre B.V. Formation of formic acid with the help of indium-containing catalytic electrode
US11053597B2 (en) * 2018-04-05 2021-07-06 Lawrence Livermore National Security, Llc Flow-through reactor for electrocatalytic reactions
WO2021207857A1 (en) * 2020-04-17 2021-10-21 The University Of British Columbia Electrolytic conversion of carbon-containing ions using porous metal electrodes
CN113646468A (en) * 2019-01-07 2021-11-12 欧普斯12股份有限公司 System and method for methane production
US11280008B2 (en) * 2016-01-02 2022-03-22 Dnv Gl As Electrochemical apparatus having tin-based cathodic catalyst
US11417901B2 (en) 2018-12-18 2022-08-16 Twelve Benefit Corporation Electrolyzer and method of use
US11512403B2 (en) 2018-01-22 2022-11-29 Twelve Benefit Corporation System and method for carbon dioxide reactor control
US11680328B2 (en) 2019-11-25 2023-06-20 Twelve Benefit Corporation Membrane electrode assembly for COx reduction
WO2023126499A2 (en) 2021-12-31 2023-07-06 Arnold Mickael Method for electrochemical reduction of liquid or supercritical co2
US11718921B2 (en) 2018-08-20 2023-08-08 Thalesnano Zrt Modular electrolyzer unit to generate gaseous hydrogen at high pressure and with high purity
WO2023201039A1 (en) * 2022-04-14 2023-10-19 William Marsh Rice University Electrochemical carbon dioxide capture and recovery in a solid electrolyte reactor system
NL2032604B1 (en) * 2022-07-26 2024-02-05 Stichting Wetsus European Centre Of Excellence For Sustainable Water Tech Method for flushing in an electromembrane process, a device, a membrane stack, and a system to perform said method.
US11920248B2 (en) 2018-12-18 2024-03-05 Prometheus Fuels, Inc Methods and systems for fuel production
US11939284B2 (en) 2022-08-12 2024-03-26 Twelve Benefit Corporation Acetic acid production
WO2024124262A1 (en) * 2022-12-12 2024-06-20 Gig Karasek Gmbh System for reducing carbon dioxide, and electrolysis cell for same
US12060483B2 (en) 2020-10-20 2024-08-13 Twelve Benefit Corporation Semi-interpenetrating and crosslinked polymers and membranes thereof

Families Citing this family (14)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
KR20150055033A (en) * 2012-09-14 2015-05-20 리퀴드 라이트 인코포레이티드 Process and high surface area electrodes for the electrochemical reduction of carbon dioxide
WO2015139136A1 (en) * 2014-03-19 2015-09-24 Brereton Clive M H Co2 electro-reduction process
KR102408081B1 (en) * 2015-07-08 2022-06-10 아고라 에너지 테크놀로지스 엘티디. Redox flow battery with carbon dioxide-based redox couple
CN108654383A (en) * 2017-04-01 2018-10-16 通用电气公司 Reduce the method and nanofiltration system of monovalention content in the final concentrate of nanofiltration system
JP6951309B2 (en) * 2018-09-18 2021-10-20 株式会社東芝 Carbon dioxide electrolyzer and carbon dioxide electrolysis method
CN110938844B (en) * 2019-11-13 2021-09-21 华南理工大学 Self-supporting three-dimensional copper-tin alloy material and preparation method and application thereof
CN111203219B (en) * 2020-03-05 2021-06-04 南昌大学 Copper-based catalyst for preparing formic acid from carbon dioxide, preparation method and application
CN113969815A (en) * 2020-07-23 2022-01-25 深圳臻宇新能源动力科技有限公司 Exhaust gas treatment device and vehicle
CA3194634A1 (en) * 2020-11-09 2022-05-12 Chengxiang Xiang Electrodialyzer and electrodialysis system for co2 capture from ocean water
US11850566B2 (en) 2020-11-24 2023-12-26 Aircela Inc. Synthetic fuel production system and related techniques
US20220204899A1 (en) * 2020-12-30 2022-06-30 Uchicago Argonne, Llc System and method for biological methane gas generation and removal of carbon dioxide therefrom
WO2023097243A1 (en) * 2021-11-24 2023-06-01 Nitto Denko Corporation Methods and system for electrochemical production of formic acid from carbon dioxide
US20240240340A1 (en) * 2023-01-11 2024-07-18 Dioxycle Separators for Liquid Products in Oxocarbon Electrolyzers
US12031221B1 (en) 2023-01-11 2024-07-09 Dioxycle Separators for liquid products in oxocarbon electrolyzers

Citations (10)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US5106465A (en) * 1989-12-20 1992-04-21 Olin Corporation Electrochemical process for producing chlorine dioxide solutions from chlorites
US5198086A (en) * 1990-12-21 1993-03-30 Allied-Signal Electrodialysis of salts of weak acids and/or weak bases
US20060102468A1 (en) * 2002-08-21 2006-05-18 Battelle Memorial Institute Photolytic oxygenator with carbon dioxide and/or hydrogen separation and fixation
US20080223727A1 (en) * 2005-10-13 2008-09-18 Colin Oloman Continuous Co-Current Electrochemical Reduction of Carbon Dioxide
US20080248350A1 (en) * 2007-04-03 2008-10-09 New Sky Energy, Inc. Electrochemical apparatus to generate hydrogen and sequester carbon dioxide
US20110083968A1 (en) * 2009-02-10 2011-04-14 Gilliam Ryan J Low-voltage alkaline production using hydrogen and electrocatalytic electrodes
WO2012046362A1 (en) * 2010-10-06 2012-04-12 パナソニック株式会社 Method for reducing carbon dioxide
US20120295172A1 (en) * 2010-01-25 2012-11-22 Emanuel Peled Electrochemical systems and methods of operating same
US20120298522A1 (en) * 2011-01-11 2012-11-29 Riyaz Shipchandler Systems and methods for soda ash production
US20120329657A1 (en) * 2007-05-04 2012-12-27 Principle Energy Solutions, Inc. Methods and devices for the production of hydrocarbons from carbon and hydrogen sources

Family Cites Families (201)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US1280622A (en) 1915-05-08 1918-10-08 Launcelot W Andrews Process for manufacturing oxalates.
US1962140A (en) 1928-04-18 1934-06-12 Dreyfus Henry Manufacture of hydroxy carboxylic acids
US2060880A (en) 1933-09-23 1936-11-17 Du Pont Process of producing ethylene glycol
FR853643A (en) 1938-05-04 1940-03-23 Ig Farbenindustrie Ag Process for producing halogenated hydrocarbons
US2967806A (en) 1953-04-02 1961-01-10 Hooker Chemical Corp Electrolytic decomposition with permselective diaphragms
US3236879A (en) 1957-10-10 1966-02-22 Montedison Spa Preparation of alpha-beta, deltaepsilon unsaturated carboxylic acids and esters
US3019256A (en) 1959-03-23 1962-01-30 Union Carbide Corp Process for producing acrylic acid esters
US3088990A (en) 1960-04-25 1963-05-07 Standard Oil Co Energy conversion system
US3220941A (en) 1960-08-03 1965-11-30 Hooker Chemical Corp Method for electrolysis
NL293359A (en) 1962-06-02
US3293292A (en) 1962-12-07 1966-12-20 Union Oil Co Butane oxidation
NL129705C (en) 1963-11-04
GB1096847A (en) 1964-03-27 1967-12-29 Ethyl Corp A process for the production of primary aliphatic hydrocarbon halides
US3352935A (en) 1964-04-20 1967-11-14 Phillips Petroleum Co Dehydrohalogenation process
US3326998A (en) 1964-04-20 1967-06-20 Phillips Petroleum Co Catalytic dehydrohalogenation of alkyl halides in presence of nitrogen-containing compounds
US3401100A (en) 1964-05-26 1968-09-10 Trw Inc Electrolytic process for concentrating carbon dioxide
US3347758A (en) 1964-09-25 1967-10-17 Mobil Oil Corp Electrochemical preparation of aromatic esters
US3344046A (en) 1964-10-23 1967-09-26 Sun Oil Co Electrolytic preparation of organic carbonates
US3341616A (en) 1966-01-10 1967-09-12 Phillips Petroleum Co Dehydrohalogenation process and catalyst
DE1618405A1 (en) 1967-04-20 1971-03-25 Bayer Ag Process for the electrochemical production of olefin oxides
US3479261A (en) 1967-05-15 1969-11-18 North American Rockwell Electrochemical method for recovery of sulfur oxides
US3560354A (en) 1967-10-16 1971-02-02 Union Oil Co Electrolytic chemical process
GB1203434A (en) 1967-10-23 1970-08-26 Ici Ltd Oxidation of organic materials
DE1668102A1 (en) 1968-02-28 1971-06-03 Hoechst Ag Process for the production of acetylene
US3649482A (en) 1968-11-04 1972-03-14 Continental Oil Co Cathodic process for the preparation of tetraalkyl lead compounds
US3636159A (en) 1968-12-19 1972-01-18 Phillips Petroleum Co Hydroformylation process and catalyst
BE787771A (en) 1971-08-20 1973-02-19 Rhone Poulenc Sa PREPARATION OF GLYOXYLIC ACID
BE791653A (en) 1971-12-28 1973-05-21 Texaco Development Corp ELECTROLYTIC PROCESS FOR THE PREPARATION OF ACID
US3764492A (en) 1972-01-10 1973-10-09 Monsanto Co Electrolytic preparation of esters from organo halides
GB1425022A (en) 1972-05-03 1976-02-18 Petrocarbon Dev Lts Process for the oxidation of olefins
US3824163A (en) 1972-07-19 1974-07-16 Electronic Associates Electrochemical sulfur dioxide abatement process
US4147599A (en) 1977-07-19 1979-04-03 Diamond Shamrock Corporation Production of alkali metal carbonates in a cell having a carboxyl membrane
DE2301032A1 (en) 1973-01-10 1974-07-25 Dechema Oxalic acid prodn. - by electro-chemical reductive dimerisation of carbon dioxide
DE2343054C2 (en) 1973-08-25 1975-10-09 Basf Ag, 6700 Ludwigshafen Process for the electrochemical production of pinacols
US3959094A (en) 1975-03-13 1976-05-25 The United States Of America As Represented By The United States Energy Research And Development Administration Electrolytic synthesis of methanol from CO2
US4088682A (en) 1975-07-03 1978-05-09 Jordan Robert Kenneth Oxalate hydrogenation process
US4087470A (en) 1976-06-23 1978-05-02 Chevron Research Company Process for the production of ethylene glycol
US4072583A (en) 1976-10-07 1978-02-07 Monsanto Company Electrolytic carboxylation of carbon acids via electrogenerated bases
JPS53101311A (en) 1977-02-10 1978-09-04 Mitsubishi Chem Ind Ltd Preparation of 1,2,3,4-butaneteracarboxylic acid
DE2814807A1 (en) 1977-04-19 1978-10-26 Standard Oil Co PROCESS FOR OXIDATING BUTANE TO ACETIC ACID
JPS53132504A (en) 1977-04-26 1978-11-18 Central Glass Co Ltd Dehalogenation of halogenated hydrocarbons
IL54408A (en) 1978-03-31 1981-09-13 Yeda Res & Dev Photosynthetic process for converting carbon dioxide to organic compounds
US4299981A (en) 1978-06-05 1981-11-10 Leonard Jackson D Preparation of formic acid by hydrolysis of methyl formate
JPS5576084A (en) 1978-12-01 1980-06-07 Takeda Chem Ind Ltd Method and apparatus for production of vitamin b1 and intermediate thereof
US4245114A (en) 1978-12-19 1981-01-13 Halcon Research And Development Corporation Glycol ester preparation
WO1980001686A1 (en) 1979-01-23 1980-07-24 Inst Elektrokhimii An Sssr Method for obtaining 1,2-dichlorethane
IT1122699B (en) 1979-08-03 1986-04-23 Oronzio De Nora Impianti RESILIENT ELECTRIC COLLECTOR AND SOLID ELECTROLYTE ELECTROCHEMISTRY INCLUDING THE SAME
GB2058839B (en) 1979-09-08 1983-02-16 Engelhard Min & Chem Photo electrochemical processes
US4267070A (en) 1979-10-30 1981-05-12 Nefedov Boris K Catalyst for the synthesis of aromatic monoisocyanates
DE3066199D1 (en) 1979-11-01 1984-02-23 Shell Int Research A process for the electroreductive preparation of organic compounds
AU547549B2 (en) 1980-01-07 1985-10-24 Bush Boake Allen Limited Preparation of hydroxy compounds by electrochemical reduction
US4253921A (en) 1980-03-10 1981-03-03 Battelle Development Corporation Electrochemical synthesis of butane-1,4-diol
US4510214A (en) 1980-10-03 1985-04-09 Tracer Technologies, Inc. Electrode with electron transfer catalyst
CH645393A5 (en) 1981-02-19 1984-09-28 Ciba Geigy Ag HARDENABLE MIXTURES OF POLYEPOXIDE COMPOUNDS AND N-CYANLACTAMES AS HARDENERS.
IL67047A0 (en) 1981-10-28 1983-02-23 Eltech Systems Corp Narrow gap electrolytic cells
US4450055A (en) 1983-03-30 1984-05-22 Celanese Corporation Electrogenerative partial oxidation of organic compounds
US4476003A (en) 1983-04-07 1984-10-09 The United States Of America As Represented By The United States Department Of Energy Chemical anchoring of organic conducting polymers to semiconducting surfaces
US4560451A (en) 1983-05-02 1985-12-24 Union Carbide Corporation Electrolytic process for the production of alkene oxides
JPS6021298A (en) 1983-07-18 1985-02-02 Fuji Photo Film Co Ltd Preparation of support for planographic printing plate
DE3334863A1 (en) 1983-09-27 1985-04-11 Basf Ag, 6700 Ludwigshafen Process for obtaining aqueous glyoxylic acid solutions
US4523981A (en) 1984-03-27 1985-06-18 Texaco Inc. Means and method for reducing carbon dioxide to provide a product
US4547271A (en) 1984-09-12 1985-10-15 Canada Packers Inc. Process for the electrochemical reduction of 7-ketolithocholic acid to ursodeoxycholic acid
US4589963A (en) 1984-12-07 1986-05-20 The Dow Chemical Company Process for the conversion of salts of carboxylic acid to their corresponding free acids
US4595465A (en) 1984-12-24 1986-06-17 Texaco Inc. Means and method for reducing carbn dioxide to provide an oxalate product
US4563254A (en) 1985-02-07 1986-01-07 Texaco Inc. Means and method for the electrochemical carbonylation of nitrobenzene or 2-5 dinitrotoluene with carbon dioxide to provide a product
US4661422A (en) 1985-03-04 1987-04-28 Institute Of Gas Technology Electrochemical production of partially oxidized organic compounds
US4673473A (en) 1985-06-06 1987-06-16 Peter G. Pa Ang Means and method for reducing carbon dioxide to a product
US4608132A (en) 1985-06-06 1986-08-26 Texaco Inc. Means and method for the electrochemical reduction of carbon dioxide to provide a product
US4608133A (en) 1985-06-10 1986-08-26 Texaco Inc. Means and method for the electrochemical reduction of carbon dioxide to provide a product
US4619743A (en) 1985-07-16 1986-10-28 Texaco Inc. Electrolytic method for reducing oxalic acid to a product
US4810596A (en) 1985-10-18 1989-03-07 Hughes Aircraft Company Sulfuric acid thermoelectrochemical system and method
US5443804A (en) 1985-12-04 1995-08-22 Solar Reactor Technologies, Inc. System for the manufacture of methanol and simultaneous abatement of emission of greenhouse gases
US4732655A (en) 1986-06-11 1988-03-22 Texaco Inc. Means and method for providing two chemical products from electrolytes
US4702973A (en) 1986-08-25 1987-10-27 Institute Of Gas Technology Dual compartment anode structure
US4756807A (en) 1986-10-09 1988-07-12 Gas Research Institute Chemically modified electrodes for the catalytic reduction of CO2
EP0283753B1 (en) 1987-03-25 1990-09-19 Degussa Aktiengesellschaft Process for the catalytic epoxidation of olefins with hydrogen peroxide
JPS6415388U (en) 1987-05-23 1989-01-26
JPS6415388A (en) 1987-07-07 1989-01-19 Terumo Corp Electrode for reducing gaseous carbon dioxide
US5155256A (en) 1988-04-11 1992-10-13 Mallinckrodt Medical, Inc. Process for preparing 2-bromoethyl acetate
US4968393A (en) 1988-04-18 1990-11-06 A. L. Sandpiper Corporation Membrane divided aqueous-nonaqueous system for electrochemical cells
DE69027304T2 (en) 1989-01-17 1997-01-23 Davy Process Technology Ltd., London Continuous process for the production of carboxylic acid esters
US4950368A (en) 1989-04-10 1990-08-21 The Electrosynthesis Co., Inc. Method for paired electrochemical synthesis with simultaneous production of ethylene glycol
EP0412175B1 (en) 1989-08-07 1992-12-02 European Atomic Energy Community (Euratom) Method for removing nitrogen compounds from a liquid
US5294319A (en) 1989-12-26 1994-03-15 Olin Corporation High surface area electrode structures for electrochemical processes
US5084148A (en) 1990-02-06 1992-01-28 Olin Corporation Electrochemical process for producing chloric acid - alkali metal chlorate mixtures
JP3038393B2 (en) 1990-05-30 2000-05-08 石川島播磨重工業株式会社 Molten carbonate fuel cell power generator with CO 2 separation device using LNG cold energy
US5074974A (en) 1990-06-08 1991-12-24 Reilly Industries, Inc. Electrochemical synthesis and simultaneous purification process
US5096054A (en) 1990-06-11 1992-03-17 Case Western Reserve University Electrochemical method for the removal of nitrogen oxides and sulfur oxides from flue gas and other sources
US5290404A (en) * 1990-10-31 1994-03-01 Reilly Industries, Inc. Electro-synthesis of alcohols and carboxylic acids from corresponding metal salts
US5107040A (en) 1991-05-15 1992-04-21 The Dow Chemical Company Dehydrohalogenation using magnesium hydroxide
US5246551A (en) 1992-02-11 1993-09-21 Chemetics International Company Ltd. Electrochemical methods for production of alkali metal hydroxides without the co-production of chlorine
ATE138425T1 (en) 1992-02-22 1996-06-15 Hoechst Ag ELECTROCHEMICAL PROCESS FOR PRODUCING GLYOXYLIC ACID
US5300369A (en) 1992-07-22 1994-04-05 Space Systems/Loral Electric energy cell with internal failure compensation
EP0614875A1 (en) 1993-03-12 1994-09-14 Ube Industries, Ltd. Method of producing a glycolic acid ester
DE4318069C1 (en) 1993-06-01 1994-03-31 Cassella Ag Prodn. of methyl 5-bromo-6-methoxy-1-naphthoate - used as tolrestat intermediate, comprises reaction of methyl 6-methoxy-1-naphthoate with bromine in presence of oxidising agent
JP3458341B2 (en) 1993-07-12 2003-10-20 有限会社コヒーレントテクノロジー Method for producing washing water containing hydrogen ions or hydroxyl ions in excess of counter ions and obtained washing water
JP3343601B2 (en) 1993-10-26 2002-11-11 関西電力株式会社 Method for producing hydrocarbons from carbon dioxide
NO300038B1 (en) 1995-05-12 1997-03-24 Norsk Hydro As Process for the preparation of products containing double salts of formic acid
US5514492A (en) 1995-06-02 1996-05-07 Pacesetter, Inc. Cathode material for use in an electrochemical cell and method for preparation thereof
DE19531408A1 (en) 1995-08-26 1997-02-27 Hoechst Ag Process for the preparation of (4-bromophenyl) alkyl ethers
DE19543678A1 (en) 1995-11-23 1997-05-28 Bayer Ag Process for direct electrochemical gas phase phosgene synthesis
IN190134B (en) 1995-12-28 2003-06-21 Du Pont
US6024935A (en) 1996-01-26 2000-02-15 Blacklight Power, Inc. Lower-energy hydrogen methods and structures
FR2747694B1 (en) 1996-04-18 1998-06-05 France Etat CATHODE FOR THE REDUCTION OF CARBON DIOXIDE AND METHOD OF MANUFACTURING SUCH A CATHODE
WO1997047052A1 (en) 1996-06-05 1997-12-11 Southwest Research Institute Cylindrical proton exchange membrane fuel cells and methods of making same
AR010696A1 (en) 1996-12-12 2000-06-28 Sasol Tech Pty Ltd A METHOD FOR THE ELIMINATION OF CARBON DIOXIDE FROM A PROCESS GAS
US5928806A (en) 1997-05-07 1999-07-27 Olah; George A. Recycling of carbon dioxide into methyl alcohol and related oxygenates for hydrocarbons
US6271400B2 (en) 1997-10-23 2001-08-07 The Scripps Research Institute Epoxidation of olefins
US6171551B1 (en) 1998-02-06 2001-01-09 Steris Corporation Electrolytic synthesis of peracetic acid and other oxidants
US20020122980A1 (en) 1998-05-19 2002-09-05 Fleischer Niles A. Electrochemical cell with a non-liquid electrolyte
US6267864B1 (en) 1998-09-14 2001-07-31 Nanomaterials Research Corporation Field assisted transformation of chemical and material compositions
JP2000104190A (en) 1998-09-30 2000-04-11 Mitsui Chemicals Inc Production of metahydroxybenzaldehyde
US6251256B1 (en) 1999-02-04 2001-06-26 Celanese International Corporation Process for electrochemical oxidation of an aldehyde to an ester
US6274009B1 (en) 1999-09-03 2001-08-14 International Dioxide Inc. Generator for generating chlorine dioxide under vacuum eduction in a single pass
DK1235772T3 (en) 1999-11-22 2005-04-11 Dow Global Technologies Inc Process for converting ethylene to vinyl chloride and novel catalyst compositions useful for such a process
DE60042195D1 (en) 1999-12-28 2009-06-25 Mitsubishi Chem Corp Process for producing diaryl carbonate
US6447943B1 (en) 2000-01-18 2002-09-10 Ramot University Authority For Applied Research & Industrial Development Ltd. Fuel cell with proton conducting membrane with a pore size less than 30 nm
KR100391845B1 (en) 2000-02-11 2003-07-16 한국과학기술연구원 Synthesis of Alkylene Carbonates using a Metal Halides Complex containing Pyridine Ligands
US6828054B2 (en) 2000-02-11 2004-12-07 The Texas A&M University System Electronically conducting fuel cell component with directly bonded layers and method for making the same
JP3505708B2 (en) 2000-06-12 2004-03-15 本田技研工業株式会社 Single cell for polymer electrolyte fuel cell, method for manufacturing the same, polymer electrolyte fuel cell, and method for regenerating the same
US6380446B1 (en) 2000-08-17 2002-04-30 Dupont Dow Elastomers, L.L.C. Process for dehydrohalogenation of halogenated compounds
TW574071B (en) 2001-06-14 2004-02-01 Rohm & Haas Mixed metal oxide catalyst
US6465699B1 (en) 2001-06-20 2002-10-15 Gri, Inc. Integrated process for synthesizing alcohols, ethers, and olefins from alkanes
US7161050B2 (en) 2001-06-20 2007-01-09 Grt, Inc. Method and apparatus for synthesizing olefins, alcohols, ethers, and aldehydes
GB0116505D0 (en) 2001-07-06 2001-08-29 Univ Belfast Electrosynthesis of organic compounds
WO2003072511A1 (en) 2002-01-24 2003-09-04 The C & M Group, Llc Mediated electrochemical oxidation of halogenated hydrocarbon waste materials
US6949178B2 (en) 2002-07-09 2005-09-27 Lynntech, Inc. Electrochemical method for preparing peroxy acids
WO2004024634A2 (en) 2002-09-10 2004-03-25 The C & M Group, Llc Mediated electrochemical oxidation of inorganic materials
US20040115489A1 (en) 2002-12-12 2004-06-17 Manish Goel Water and energy management system for a fuel cell
EP1443091A1 (en) 2003-01-31 2004-08-04 Ntera Limited Electrochromic compounds
BRPI0410478A (en) 2003-05-19 2008-04-08 Michael C Trachtenberg gas separation methods, apparatus, and reactors
US7378011B2 (en) 2003-07-28 2008-05-27 Phelps Dodge Corporation Method and apparatus for electrowinning copper using the ferrous/ferric anode reaction
FR2863911B1 (en) 2003-12-23 2006-04-07 Inst Francais Du Petrole CARBON SEQUESTRATION PROCESS IN THE FORM OF A MINERAL IN WHICH THE CARBON IS AT THE DEGREE OF OXIDATION +3
US10629947B2 (en) 2008-08-05 2020-04-21 Sion Power Corporation Electrochemical cell
US7462752B2 (en) 2004-04-21 2008-12-09 Shell Oil Company Process to convert linear alkanes into alpha olefins
WO2005104275A1 (en) 2004-04-22 2005-11-03 Nippon Steel Corporation Fuel cell and gas diffusion electrode for fuel cell
JP5114823B2 (en) 2004-05-31 2013-01-09 日産自動車株式会社 Photoelectrochemical cell
JP2008535778A (en) 2005-01-07 2008-09-04 コンビマトリックス・コーポレイション Method for electrochemically performing isolated Pd (0) catalytic reaction with an electrode array device
US9057136B2 (en) 2005-04-12 2015-06-16 University Of South Carolina Production of low temperature electrolytic hydrogen
US7767358B2 (en) 2005-05-31 2010-08-03 Nextech Materials, Ltd. Supported ceramic membranes and electrochemical cells and cell stacks including the same
DE102005032663A1 (en) 2005-07-13 2007-01-18 Bayer Materialscience Ag Process for the preparation of isocyanates
US20100130768A1 (en) 2005-10-05 2010-05-27 Daiichi Sankyo Company, Limited Method for hydrodehalogenation of organic halogen compound
US20090062110A1 (en) 2006-02-08 2009-03-05 Sumitomo Chemical Company Limited Metal complex and use thereof
ATE545456T1 (en) 2006-04-27 2012-03-15 Harvard College CARBON DIOXIDE COLLECTION AND RELATED METHODS
SE530266C2 (en) 2006-06-16 2008-04-15 Morphic Technologies Ab Publ Process and reactor for the production of methanol
EP1933330A1 (en) 2006-12-11 2008-06-18 Trasis S.A. Electrochemical 18F extraction, concentration and reformulation method for radiolabeling
FI121271B (en) 2007-01-19 2010-09-15 Outotec Oyj Process for the preparation of hydrogen and sulfuric acid
AP2009005040A0 (en) 2007-05-14 2009-12-31 Grt Inc Process for converting hydrocarbon feedstocks withelectrolytic recovery of halogen
TW200911693A (en) 2007-06-12 2009-03-16 Solvay Aqueous composition containing a salt, manufacturing process and use
US7906559B2 (en) 2007-06-21 2011-03-15 University Of Southern California Conversion of carbon dioxide to methanol and/or dimethyl ether using bi-reforming of methane or natural gas
TW200920721A (en) 2007-07-13 2009-05-16 Solvay Fluor Gmbh Preparation of halogen and hydrogen containing alkenes over metal fluoride catalysts
CN101743343B (en) 2007-07-13 2012-07-04 南加州大学 Electrolysis of carbon dioxide in aqueous media to carbon monoxide and hydrogen for production of methanol
US8152988B2 (en) 2007-08-31 2012-04-10 Energy & Enviromental Research Center Foundation Electrochemical process for the preparation of nitrogen fertilizers
TWI423946B (en) 2007-11-14 2014-01-21 Shell Int Research Process for the preparation of alkylene glycol
JP5439757B2 (en) 2007-12-07 2014-03-12 ソニー株式会社 Fuel cells and electronics
EP2078697A1 (en) 2008-01-08 2009-07-15 SOLVAY (Société Anonyme) Process for producing sodium carbonate and/or sodium bicarbonate from an ore mineral comprising sodium bicarbonate
WO2009108327A1 (en) 2008-02-26 2009-09-03 Grimes, Maureen A. Production of hydrocarbons from carbon dioxide and water
US8282810B2 (en) 2008-06-13 2012-10-09 Marathon Gtf Technology, Ltd. Bromine-based method and system for converting gaseous alkanes to liquid hydrocarbons using electrolysis for bromine recovery
WO2010008836A2 (en) 2008-06-23 2010-01-21 Arizona Board Of Regents For And On Behalf Of Arizona State University Bicarbonate and carbonate as hydroxide carriers in a biological fuel cell
US7993500B2 (en) 2008-07-16 2011-08-09 Calera Corporation Gas diffusion anode and CO2 cathode electrolyte system
JP5493572B2 (en) 2008-08-11 2014-05-14 株式会社豊田中央研究所 Photocatalyst and reduction catalyst using the same
US8313634B2 (en) 2009-01-29 2012-11-20 Princeton University Conversion of carbon dioxide to organic products
US8163429B2 (en) 2009-02-05 2012-04-24 Ini Power Systems, Inc. High efficiency fuel cell system
FR2944031B1 (en) 2009-04-06 2013-06-14 Commissariat Energie Atomique ELECTROCHEMICAL CELL WITH ELECTROLYTE FLOW COMPRISING THROUGH ELECTRODES AND METHOD OF MANUFACTURE
US20100270167A1 (en) 2009-04-22 2010-10-28 Mcfarland Eric Process for converting hydrocarbon feedstocks with electrolytic and photoelectrocatalytic recovery of halogens
US9099720B2 (en) 2009-05-29 2015-08-04 Medtronic, Inc. Elongate battery for implantable medical device
US7993511B2 (en) 2009-07-15 2011-08-09 Calera Corporation Electrochemical production of an alkaline solution using CO2
WO2011011521A2 (en) 2009-07-23 2011-01-27 Ceramatec, Inc. Decarboxylation cell for production of coupled radical products
CA2782690A1 (en) 2009-12-02 2011-06-09 Board Of Trustees Of Michigan State University Carboxylic acid recovery and methods related thereto
CN102341529A (en) 2009-12-04 2012-02-01 松下电器产业株式会社 Method for reducing carbon dioxide, and carbon dioxide reduction catalyst and carbon dioxide reduction apparatus used therein
US20110114502A1 (en) 2009-12-21 2011-05-19 Emily Barton Cole Reducing carbon dioxide to products
WO2011094153A1 (en) 2010-01-29 2011-08-04 Conocophillips Company Electrolytic recovery of retained carbon dioxide
US8703089B2 (en) 2010-03-03 2014-04-22 Ino Therapeutics Llc Method and apparatus for the manufacture of high purity carbon monoxide
CN102906925B (en) 2010-03-18 2016-05-25 布莱克光电有限公司 Electrochemical hydrogen catalyst dynamical system
US8845877B2 (en) 2010-03-19 2014-09-30 Liquid Light, Inc. Heterocycle catalyzed electrochemical process
US8721866B2 (en) 2010-03-19 2014-05-13 Liquid Light, Inc. Electrochemical production of synthesis gas from carbon dioxide
US8500987B2 (en) 2010-03-19 2013-08-06 Liquid Light, Inc. Purification of carbon dioxide from a mixture of gases
US20110237830A1 (en) 2010-03-26 2011-09-29 Dioxide Materials Inc Novel catalyst mixtures
CN101879448B (en) 2010-06-24 2012-05-23 天津大学 Regular structure catalyst for preparing ethylene glycol by hydrogenation of oxalate and preparation method thereof
US8933265B2 (en) 2010-06-30 2015-01-13 Uop Llc Process for oxidizing alkyl aromatic compounds
US8884054B2 (en) 2010-06-30 2014-11-11 Uop Llc Process for oxidizing alkyl aromatic compounds
US9045407B2 (en) 2010-06-30 2015-06-02 Uop Llc Mixtures used in oxidizing alkyl aromatic compounds
US8845878B2 (en) 2010-07-29 2014-09-30 Liquid Light, Inc. Reducing carbon dioxide to products
US20130180865A1 (en) 2010-07-29 2013-07-18 Liquid Light, Inc. Reducing Carbon Dioxide to Products
US8524066B2 (en) 2010-07-29 2013-09-03 Liquid Light, Inc. Electrochemical production of urea from NOx and carbon dioxide
US9062388B2 (en) 2010-08-19 2015-06-23 International Business Machines Corporation Method and apparatus for controlling and monitoring the potential
US8389178B2 (en) 2010-09-10 2013-03-05 U.S. Department Of Energy Electrochemical energy storage device based on carbon dioxide as electroactive species
CA2810894C (en) * 2010-09-24 2019-12-31 Det Norske Veritas As Method and apparatus for the electrochemical reduction of carbon dioxide
US8568581B2 (en) 2010-11-30 2013-10-29 Liquid Light, Inc. Heterocycle catalyzed carbonylation and hydroformylation with carbon dioxide
US8961774B2 (en) 2010-11-30 2015-02-24 Liquid Light, Inc. Electrochemical production of butanol from carbon dioxide and water
US9090976B2 (en) 2010-12-30 2015-07-28 The Trustees Of Princeton University Advanced aromatic amine heterocyclic catalysts for carbon dioxide reduction
JP6021074B2 (en) 2011-02-28 2016-11-02 国立大学法人長岡技術科学大学 Carbon dioxide reduction and fixation system, carbon dioxide reduction and fixation method, and method for producing useful carbon resources
US8562811B2 (en) 2011-03-09 2013-10-22 Liquid Light, Inc. Process for making formic acid
CN102190573B (en) 2011-03-30 2013-11-27 昆明理工大学 Method for preparing formic acid through electrochemical catalytic reduction of carbon dioxide
SA112330516B1 (en) 2011-05-19 2016-02-22 كاليرا كوربوريشن Electrochemical hydroxide systems and methods using metal oxidation
WO2012166997A2 (en) 2011-05-31 2012-12-06 Clean Chemistry, Llc Electrochemical reactor and process
WO2013006711A1 (en) 2011-07-06 2013-01-10 Liquid Light, Inc. Reduction of carbon dioxide to carboxylic acids, glycols, and carboxylates
WO2013031063A1 (en) 2011-08-31 2013-03-07 パナソニック株式会社 Method for reducing carbon dioxide
US8641885B2 (en) 2012-07-26 2014-02-04 Liquid Light, Inc. Multiphase electrochemical reduction of CO2
US8845875B2 (en) 2012-07-26 2014-09-30 Liquid Light, Inc. Electrochemical reduction of CO2 with co-oxidation of an alcohol
US20130105304A1 (en) 2012-07-26 2013-05-02 Liquid Light, Inc. System and High Surface Area Electrodes for the Electrochemical Reduction of Carbon Dioxide

Patent Citations (11)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US5106465A (en) * 1989-12-20 1992-04-21 Olin Corporation Electrochemical process for producing chlorine dioxide solutions from chlorites
US5198086A (en) * 1990-12-21 1993-03-30 Allied-Signal Electrodialysis of salts of weak acids and/or weak bases
US20060102468A1 (en) * 2002-08-21 2006-05-18 Battelle Memorial Institute Photolytic oxygenator with carbon dioxide and/or hydrogen separation and fixation
US20080223727A1 (en) * 2005-10-13 2008-09-18 Colin Oloman Continuous Co-Current Electrochemical Reduction of Carbon Dioxide
US20080248350A1 (en) * 2007-04-03 2008-10-09 New Sky Energy, Inc. Electrochemical apparatus to generate hydrogen and sequester carbon dioxide
US20120329657A1 (en) * 2007-05-04 2012-12-27 Principle Energy Solutions, Inc. Methods and devices for the production of hydrocarbons from carbon and hydrogen sources
US20110083968A1 (en) * 2009-02-10 2011-04-14 Gilliam Ryan J Low-voltage alkaline production using hydrogen and electrocatalytic electrodes
US20120295172A1 (en) * 2010-01-25 2012-11-22 Emanuel Peled Electrochemical systems and methods of operating same
WO2012046362A1 (en) * 2010-10-06 2012-04-12 パナソニック株式会社 Method for reducing carbon dioxide
US20130062216A1 (en) * 2010-10-06 2013-03-14 Panasonic Corporation Method for reducing carbon dioxide
US20120298522A1 (en) * 2011-01-11 2012-11-29 Riyaz Shipchandler Systems and methods for soda ash production

Cited By (135)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US8986533B2 (en) 2009-01-29 2015-03-24 Princeton University Conversion of carbon dioxide to organic products
US8663447B2 (en) 2009-01-29 2014-03-04 Princeton University Conversion of carbon dioxide to organic products
US10115972B2 (en) 2009-04-30 2018-10-30 University Of Florida Research Foundation, Incorporated Single wall carbon nanotube based air cathodes
US9970117B2 (en) 2010-03-19 2018-05-15 Princeton University Heterocycle catalyzed electrochemical process
US8845877B2 (en) 2010-03-19 2014-09-30 Liquid Light, Inc. Heterocycle catalyzed electrochemical process
US8721866B2 (en) 2010-03-19 2014-05-13 Liquid Light, Inc. Electrochemical production of synthesis gas from carbon dioxide
US10119196B2 (en) 2010-03-19 2018-11-06 Avantium Knowledge Centre B.V. Electrochemical production of synthesis gas from carbon dioxide
US9222179B2 (en) 2010-03-19 2015-12-29 Liquid Light, Inc. Purification of carbon dioxide from a mixture of gases
US10023967B2 (en) 2010-03-26 2018-07-17 Dioxide Materials, Inc. Electrochemical devices employing novel catalyst mixtures
US9957624B2 (en) * 2010-03-26 2018-05-01 Dioxide Materials, Inc. Electrochemical devices comprising novel catalyst mixtures
US10173169B2 (en) 2010-03-26 2019-01-08 Dioxide Materials, Inc Devices for electrocatalytic conversion of carbon dioxide
US9849450B2 (en) 2010-07-04 2017-12-26 Dioxide Materials, Inc. Ion-conducting membranes
US9945040B2 (en) * 2010-07-04 2018-04-17 Dioxide Materials, Inc. Catalyst layers and electrolyzers
US9580824B2 (en) 2010-07-04 2017-02-28 Dioxide Materials, Inc. Ion-conducting membranes
US10047446B2 (en) 2010-07-04 2018-08-14 Dioxide Materials, Inc. Method and system for electrochemical production of formic acid from carbon dioxide
US20160369415A1 (en) * 2010-07-04 2016-12-22 Dioxide Materials, Inc. Catalyst Layers And Electrolyzers
US9481939B2 (en) 2010-07-04 2016-11-01 Dioxide Materials, Inc. Electrochemical device for converting carbon dioxide to a reaction product
US9370773B2 (en) 2010-07-04 2016-06-21 Dioxide Materials, Inc. Ion-conducting membranes
US8845878B2 (en) 2010-07-29 2014-09-30 Liquid Light, Inc. Reducing carbon dioxide to products
US20130180865A1 (en) * 2010-07-29 2013-07-18 Liquid Light, Inc. Reducing Carbon Dioxide to Products
US8961774B2 (en) 2010-11-30 2015-02-24 Liquid Light, Inc. Electrochemical production of butanol from carbon dioxide and water
US9309599B2 (en) 2010-11-30 2016-04-12 Liquid Light, Inc. Heterocycle catalyzed carbonylation and hydroformylation with carbon dioxide
US9768460B2 (en) 2010-12-17 2017-09-19 University Of Florida Research Foundation, Inc. Hydrogen oxidation and generation over carbon films
US10181614B2 (en) 2010-12-17 2019-01-15 University Of Florida Research Foundation, Incorporated Hydrogen oxidation and generation over carbon films
US9742018B2 (en) 2010-12-17 2017-08-22 University Of Florida Research Foundation, Inc. Hydrogen oxidation and generation over carbon films
US9090976B2 (en) 2010-12-30 2015-07-28 The Trustees Of Princeton University Advanced aromatic amine heterocyclic catalysts for carbon dioxide reduction
US9642252B2 (en) 2011-04-04 2017-05-02 University Of Florida Research Foundation, Inc. Nanotube dispersants and dispersant free nanotube films therefrom
US9642253B2 (en) 2011-04-04 2017-05-02 University Of Florida Research Foundation, Inc. Nanotube dispersants and dispersant free nanotube films therefrom
US9775241B2 (en) 2011-04-04 2017-09-26 University Of Florida Research Foundation, Inc. Nanotube dispersants and dispersant free nanotube films therefrom
US8658016B2 (en) 2011-07-06 2014-02-25 Liquid Light, Inc. Carbon dioxide capture and conversion to organic products
US9943841B2 (en) 2012-04-12 2018-04-17 Dioxide Materials, Inc. Method of making an anion exchange membrane
US20170233881A1 (en) * 2012-04-12 2017-08-17 Dioxide Materials, Inc. Water Electrolyzers
US9982353B2 (en) * 2012-04-12 2018-05-29 Dioxide Materials, Inc. Water electrolyzers
US9080240B2 (en) 2012-07-26 2015-07-14 Liquid Light, Inc. Electrochemical co-production of a glycol and an alkene employing recycled halide
US8821709B2 (en) 2012-07-26 2014-09-02 Liquid Light, Inc. System and method for oxidizing organic compounds while reducing carbon dioxide
US8641885B2 (en) 2012-07-26 2014-02-04 Liquid Light, Inc. Multiphase electrochemical reduction of CO2
US9303324B2 (en) 2012-07-26 2016-04-05 Liquid Light, Inc. Electrochemical co-production of chemicals with sulfur-based reactant feeds to anode
US10287696B2 (en) 2012-07-26 2019-05-14 Avantium Knowledge Centre B.V. Process and high surface area electrodes for the electrochemical reduction of carbon dioxide
US8647493B2 (en) 2012-07-26 2014-02-11 Liquid Light, Inc. Electrochemical co-production of chemicals employing the recycling of a hydrogen halide
US8691069B2 (en) 2012-07-26 2014-04-08 Liquid Light, Inc. Method and system for the electrochemical co-production of halogen and carbon monoxide for carbonylated products
US8858777B2 (en) 2012-07-26 2014-10-14 Liquid Light, Inc. Process and high surface area electrodes for the electrochemical reduction of carbon dioxide
US8692019B2 (en) 2012-07-26 2014-04-08 Liquid Light, Inc. Electrochemical co-production of chemicals utilizing a halide salt
US9085827B2 (en) 2012-07-26 2015-07-21 Liquid Light, Inc. Integrated process for producing carboxylic acids from carbon dioxide
US9175409B2 (en) 2012-07-26 2015-11-03 Liquid Light, Inc. Multiphase electrochemical reduction of CO2
US10329676B2 (en) 2012-07-26 2019-06-25 Avantium Knowledge Centre B.V. Method and system for electrochemical reduction of carbon dioxide employing a gas diffusion electrode
US11131028B2 (en) 2012-07-26 2021-09-28 Avantium Knowledge Centre B.V. Method and system for electrochemical reduction of carbon dioxide employing a gas diffusion electrode
US8845875B2 (en) 2012-07-26 2014-09-30 Liquid Light, Inc. Electrochemical reduction of CO2 with co-oxidation of an alcohol
US9175407B2 (en) 2012-07-26 2015-11-03 Liquid Light, Inc. Integrated process for producing carboxylic acids from carbon dioxide
US9267212B2 (en) 2012-07-26 2016-02-23 Liquid Light, Inc. Method and system for production of oxalic acid and oxalic acid reduction products
US8845876B2 (en) 2012-07-26 2014-09-30 Liquid Light, Inc. Electrochemical co-production of products with carbon-based reactant feed to anode
US9708722B2 (en) 2012-07-26 2017-07-18 Avantium Knowledge Centre B.V. Electrochemical co-production of products with carbon-based reactant feed to anode
US9873951B2 (en) 2012-09-14 2018-01-23 Avantium Knowledge Centre B.V. High pressure electrochemical cell and process for the electrochemical reduction of carbon dioxide
US10975481B2 (en) * 2012-12-06 2021-04-13 Tsinghua University Cathode catalyst, cathode material using the same, and reactor using the same
US10647652B2 (en) 2013-02-24 2020-05-12 Dioxide Materials, Inc. Process for the sustainable production of acrylic acid
WO2015077508A1 (en) * 2013-11-20 2015-05-28 University Of Florida Research Foundation, Inc. Carbon dioxide reduction over carbon-containing materials
CN105764838A (en) * 2013-11-20 2016-07-13 佛罗里达大学研究基金会有限公司 Carbon dioxide reduction over carbon-containing materials
US10815576B2 (en) 2013-11-20 2020-10-27 University Of Florida Research Foundation, Incorporated Carbon dioxide reduction over carbon-containing materials
JP2017504547A (en) * 2013-11-20 2017-02-09 ユニバーシティー オブ フロリダ リサーチ ファウンデーション,インコーポレイテッドUniversity Of Florida Research Foundation,Inc. Reduction of carbon dioxide with carbon-containing materials
WO2015143560A1 (en) * 2014-03-25 2015-10-01 Colin Oloman Process for the conversion of carbon dioxide to formic acid
CN103952717A (en) * 2014-05-07 2014-07-30 北京化工大学 Photoelectrochemical decomposition water and organic synthesis coupled cascade reaction design method
EP3157897A4 (en) * 2014-06-19 2018-03-21 Avantium Knowledge Centre B.V. Integrated process for co-production of carboxylic acids and halogen products from carbon dioxide
EP3680365A1 (en) * 2014-06-19 2020-07-15 Avantium Knowledge Centre B.V. Integrated method for producing oxalic acid and co-products
WO2016030749A1 (en) * 2014-08-29 2016-03-03 King Abdullah University Of Science And Technology Electrodes, methods of making electrodes, and methods of using electrodes
WO2016054400A1 (en) * 2014-10-01 2016-04-07 Anne Co Materials and methods for the electrochemical reduction of carbon dioxide
US10774431B2 (en) 2014-10-21 2020-09-15 Dioxide Materials, Inc. Ion-conducting membranes
US10428432B2 (en) 2014-10-21 2019-10-01 Dioxide Materials, Inc. Catalyst layers and electrolyzers
US10724142B2 (en) 2014-10-21 2020-07-28 Dioxide Materials, Inc. Water electrolyzers employing anion exchange membranes
US10443136B2 (en) * 2014-11-28 2019-10-15 Kabushiki Kaisha Toshiba Electrochemical reaction device
US20170130342A1 (en) * 2014-11-28 2017-05-11 Kabushiki Kaisha Toshiba Electrochemical reaction device
US20160222528A1 (en) * 2015-02-03 2016-08-04 Alstom Technology Ltd Method for electrochemical reduction of co2 in an electrochemical cell
US10975480B2 (en) 2015-02-03 2021-04-13 Dioxide Materials, Inc. Electrocatalytic process for carbon dioxide conversion
US20180127668A1 (en) * 2015-05-05 2018-05-10 Dioxide Materials, Inc. System And Process For The Production Of Renewable Fuels And Chemicals
US10280378B2 (en) * 2015-05-05 2019-05-07 Dioxide Materials, Inc System and process for the production of renewable fuels and chemicals
RU2685421C1 (en) * 2015-05-22 2019-04-18 Сименс Акциенгезелльшафт Electrolysis system for electrochemical utilization of carbon dioxide with proton-donating unit and method of restore
WO2016188829A1 (en) * 2015-05-22 2016-12-01 Siemens Aktiengesellschaft Electrolysis system for the electrochemical utilization of carbon dioxide, having a proton donor unit, and reduction method
DE102015209509A1 (en) * 2015-05-22 2016-11-24 Siemens Aktiengesellschaft Electrolysis system for electrochemical carbon dioxide utilization with proton donor unit and reduction process
CN107849714A (en) * 2015-05-22 2018-03-27 西门子公司 The electrolysis system and restoring method that are used for electrochemistry and utilize carbon dioxide with proton donor unit
JP2017001013A (en) * 2015-06-04 2017-01-05 株式会社豊田中央研究所 Electrode catalyst for carbon dioxide reduction, electrode, device and catalyst fixing method
US10760170B2 (en) * 2015-07-03 2020-09-01 Siemens Aktiengesellschaft Reduction method and electrolysis system for electrochemical carbon dioxide utilization
US20180179649A1 (en) * 2015-07-03 2018-06-28 Siemens Aktiengesellschaft Reduction Method And Electrolysis System For Electrochemical Carbon Dioxide Utilization
WO2017014635A1 (en) 2015-07-22 2017-01-26 Coval Energy Ventures B.V. Method and reactor for electrochemically reducing carbon dioxide
JP2017057438A (en) * 2015-09-14 2017-03-23 株式会社東芝 Reduction electrode and method of manufacturing the same, and electrolytic apparatus
US11434575B2 (en) 2015-09-14 2022-09-06 Kabushiki Kaisha Toshiba Reduction electrode and manufacturing method thereof, and electrolytic device
US11280008B2 (en) * 2016-01-02 2022-03-22 Dnv Gl As Electrochemical apparatus having tin-based cathodic catalyst
WO2017118712A1 (en) * 2016-01-05 2017-07-13 Avantium Holding B.V. Method and system for electrochemical reduction of carbon dioxide employing a gas diffusion anode
EP3473750A4 (en) * 2016-03-29 2020-04-22 Techwin Co., Ltd. Electrolysis system and electrolysis method using same
JP2019513895A (en) * 2016-04-04 2019-05-30 ダイオキサイド マテリアルズ,インコーポレイティド Water electrolytic cell
JP2019519668A (en) * 2016-04-04 2019-07-11 ダイオキサイド マテリアルズ,インコーポレイティド Ion conductive membrane
JP2019510884A (en) * 2016-04-04 2019-04-18 ダイオキサイド マテリアルズ,インコーポレイティド Catalyst layer and electrolytic cell
US10648091B2 (en) 2016-05-03 2020-05-12 Opus 12 Inc. Reactor with advanced architecture for the electrochemical reaction of CO2, CO, and other chemical compounds
US10822709B2 (en) 2016-05-03 2020-11-03 Opus 12 Incorporated Reactor with advanced architecture for the electrochemical reaction of CO2, CO and other chemical compounds
US11124886B2 (en) 2016-05-03 2021-09-21 Opus 12 Incorporated Reactor with advanced architecture for the electrochemical reaction of CO2, CO, and other chemical compounds
US11680327B2 (en) 2016-05-03 2023-06-20 Twelve Benefit Corporation Reactor with advanced architecture for the electrochemical reaction of CO2, CO and other chemical compounds
US20180030604A1 (en) * 2016-08-01 2018-02-01 Fujitsu Limited Carbon dioxide-reduction device
CN109642332A (en) * 2016-08-29 2019-04-16 二氧化碳材料公司 System and method for producing recyclable fuel and chemicals
AU2017337208B2 (en) * 2016-09-27 2019-12-12 Siemens Aktiengesellschaft Method and device for the electrochemical utilization of carbon dioxide
WO2018059839A1 (en) * 2016-09-27 2018-04-05 Siemens Aktiengesellschaft Method and device for the electrochemical utilization of carbon dioxide
CN109790632A (en) * 2016-09-27 2019-05-21 西门子股份公司 The method and apparatus for utilizing carbon dioxide for electrochemistry
US20180312786A1 (en) * 2017-04-26 2018-11-01 Kunshan Nano New Material Technology Co.,Ltd Nano super ion water and preparation method of the same
US10396329B2 (en) 2017-05-01 2019-08-27 Dioxide Materials, Inc. Battery separator membrane and battery employing same
US10147974B2 (en) 2017-05-01 2018-12-04 Dioxide Materials, Inc Battery separator membrane and battery employing same
WO2019025092A1 (en) * 2017-08-03 2019-02-07 Siemens Aktiengesellschaft Device and method for the electrochemical utilisation of carbon dioxide
US10975477B2 (en) * 2017-10-02 2021-04-13 Battelle Energy Alliance, Llc Methods and systems for the electrochemical reduction of carbon dioxide using switchable polarity materials
US11000027B2 (en) * 2017-10-17 2021-05-11 Geka Solutions Pty Ltd Pest control system
WO2019141827A1 (en) * 2018-01-18 2019-07-25 Avantium Knowledge Centre B.V. Catalyst system for catalyzed electrochemical reactions and preparation thereof, applications and uses thereof
US11512403B2 (en) 2018-01-22 2022-11-29 Twelve Benefit Corporation System and method for carbon dioxide reactor control
US11542613B2 (en) 2018-04-05 2023-01-03 Lawrence Livermore National Security, Llc Flow-through reactor for electrocatalytic reactions
US11053597B2 (en) * 2018-04-05 2021-07-06 Lawrence Livermore National Security, Llc Flow-through reactor for electrocatalytic reactions
CN108796548A (en) * 2018-07-05 2018-11-13 哈尔滨工业大学 The method that electro-catalysis reduction carbon dioxide prepares formic acid and acetic acid in heteropolyacid anions-acetonitrile-water ternary electrolyte system
US11718921B2 (en) 2018-08-20 2023-08-08 Thalesnano Zrt Modular electrolyzer unit to generate gaseous hydrogen at high pressure and with high purity
WO2020112919A1 (en) * 2018-11-28 2020-06-04 Opus 12, Inc. Electrolyzer and method of use
US12043912B2 (en) 2018-11-28 2024-07-23 Twelve Benefit Corporation Electrolyzer and method of use
CN113227457A (en) * 2018-11-28 2021-08-06 欧普斯12股份有限公司 Electrolysis device and method of use
US11578415B2 (en) 2018-11-28 2023-02-14 Twelve Benefit Corporation Electrolyzer and method of use
US11888191B2 (en) 2018-12-18 2024-01-30 Twelve Benefit Corporation Electrolyzer and method of use
US11417901B2 (en) 2018-12-18 2022-08-16 Twelve Benefit Corporation Electrolyzer and method of use
US11920248B2 (en) 2018-12-18 2024-03-05 Prometheus Fuels, Inc Methods and systems for fuel production
CN109675586A (en) * 2018-12-26 2019-04-26 厦门大学 The catalyst and preparation method thereof of electroreduction carbon dioxide formic acid
CN113646468A (en) * 2019-01-07 2021-11-12 欧普斯12股份有限公司 System and method for methane production
US12116683B2 (en) 2019-01-07 2024-10-15 Twelve Benefit Corporation System and method for methane production
CN110117794A (en) * 2019-05-21 2019-08-13 盐城工学院 A kind of electroreduction CO2The three Room type electrolytic cell devices and its electrolytic method of formates processed
WO2020240218A1 (en) 2019-05-25 2020-12-03 Szegedi Tudományegyetem Modular electrolyzer cell and process to convert carbon dioxide to gaseous products at elevated pressure and with high conversion rate
JP2021046575A (en) * 2019-09-17 2021-03-25 株式会社東芝 Carbon dioxide electrolytic device and carbon dioxide electrolytic method
JP7204619B2 (en) 2019-09-17 2023-01-16 株式会社東芝 Carbon dioxide electrolysis device and carbon dioxide electrolysis method
US11680328B2 (en) 2019-11-25 2023-06-20 Twelve Benefit Corporation Membrane electrode assembly for COx reduction
WO2021122323A1 (en) 2019-12-20 2021-06-24 Avantium Knowledge Centre B.V. Formation of formic acid with the help of indium-containing catalytic electrode
CN111304672A (en) * 2020-03-18 2020-06-19 大连理工大学 H-shaped fixed bed carbon dioxide reduction electrolytic cell and application
WO2021207857A1 (en) * 2020-04-17 2021-10-21 The University Of British Columbia Electrolytic conversion of carbon-containing ions using porous metal electrodes
US12060483B2 (en) 2020-10-20 2024-08-13 Twelve Benefit Corporation Semi-interpenetrating and crosslinked polymers and membranes thereof
FR3131589A1 (en) 2021-12-31 2023-07-07 Mickaël ARNOLD PROCESS FOR THE ELECTROCHEMICAL REDUCTION OF LIQUID OR SUPERCRITICAL CO2
WO2023126499A2 (en) 2021-12-31 2023-07-06 Arnold Mickael Method for electrochemical reduction of liquid or supercritical co2
WO2023201039A1 (en) * 2022-04-14 2023-10-19 William Marsh Rice University Electrochemical carbon dioxide capture and recovery in a solid electrolyte reactor system
NL2032604B1 (en) * 2022-07-26 2024-02-05 Stichting Wetsus European Centre Of Excellence For Sustainable Water Tech Method for flushing in an electromembrane process, a device, a membrane stack, and a system to perform said method.
US11939284B2 (en) 2022-08-12 2024-03-26 Twelve Benefit Corporation Acetic acid production
WO2024124262A1 (en) * 2022-12-12 2024-06-20 Gig Karasek Gmbh System for reducing carbon dioxide, and electrolysis cell for same

Also Published As

Publication number Publication date
US20140367273A1 (en) 2014-12-18
US10287696B2 (en) 2019-05-14
US20130180863A1 (en) 2013-07-18
US8858777B2 (en) 2014-10-14

Similar Documents

Publication Publication Date Title
US10287696B2 (en) Process and high surface area electrodes for the electrochemical reduction of carbon dioxide
EP2895642B1 (en) Process using high surface area electrodes for the electrochemical reduction of carbon dioxide
US11932954B2 (en) Two-membrane construction for electrochemically reducing CO2
US9873951B2 (en) High pressure electrochemical cell and process for the electrochemical reduction of carbon dioxide
US9303324B2 (en) Electrochemical co-production of chemicals with sulfur-based reactant feeds to anode
Albo et al. Towards the electrochemical conversion of carbon dioxide into methanol
EP2898118B1 (en) A method and system for the electrochemical co-production of halogen and carbon monoxide for carbonylated products
EP2898117B1 (en) Integrated process for producing oxalic acid from carbon dioxide
US12018393B2 (en) Separatorless dual GDE cell for electrochemical reactions
WO2017118712A1 (en) Method and system for electrochemical reduction of carbon dioxide employing a gas diffusion anode
AU2018232301A1 (en) Electrodes comprising metal introduced into a solid-state electrolyte
WO2023004505A1 (en) Use of a porous recycling layer for co2 electroreduction to multicarbon products with high conversion efficiency
Wei Electrochemical nitrogen reduction for ammonia synthesis using gas diffusion electrodes
CN114540838A (en) Diaphragm electrolysis method for preparing carbon monoxide and hypochlorite in micro-gap electrolytic cell
Proietto et al. Electrochemical conversion of pressurized CO

Legal Events

Date Code Title Description
AS Assignment

Owner name: LIQUID LIGHT, INC., NEW JERSEY

Free format text: ASSIGNMENT OF ASSIGNORS INTEREST;ASSIGNORS:KACZUR, JERRY C.;KRAMER, THEODORE J.;MAJSZTRIK, PAUL;AND OTHERS;SIGNING DATES FROM 20130109 TO 20130304;REEL/FRAME:030286/0737

AS Assignment

Owner name: LIQUID LIGHT, INC., NEW JERSEY

Free format text: ASSIGNMENT OF ASSIGNORS INTEREST;ASSIGNORS:KACZUR, JERRY J.;KRAMER, THEODORE J.;MAJSZTRIK, PAUL;AND OTHERS;SIGNING DATES FROM 20130507 TO 20130509;REEL/FRAME:030392/0059

AS Assignment

Owner name: LIQUID LIGHT, INC., NEW JERSEY

Free format text: CORRECTIVE ASSIGNMENT TO CORRECT THE TO REMOVE AN INCORRECT APPLICATION NUMBER PREVIOUSLY RECORDED ON REEL 030286 FRAME 0737. ASSIGNOR(S) HEREBY CONFIRMS THE TO CORRECT THE APPLICATION NUMBER FROM 13/724,998 TO 13/724,988;ASSIGNORS:KACZUR, JERRY J.;KRAMER, THEODORE J.;MAJSZTRIK, PAUL;AND OTHERS;SIGNING DATES FROM 20130507 TO 20130509;REEL/FRAME:030408/0923

STCB Information on status: application discontinuation

Free format text: ABANDONED -- FAILURE TO RESPOND TO AN OFFICE ACTION