CN108075140A - A kind of preparation method and application of platinum base alloy elctro-catalyst - Google Patents

Abstract

The invention belongs to noble metal electrocatalyst fields, are related to a kind of preparation method and application of platinum base alloy elctro-catalyst.The platinum carbon catalyst, alkaline matter and X salting liquids of platinum containing amount 30wt%~70wt% are uniformly mixed preparation suspension, the X is transition metal；More than the condensing reflux 0.5h at 100 200 DEG C, staticly settles, and removes supernatant, washs to neutrality, vacuum drying；Under the reducing atmosphere containing hydrogen, 0.5 3h is heat-treated at 600 800 DEG C；Platinum X-alloy carbon compound described in pickling is to obtain the platinum base alloy elctro-catalyst.The present invention is simple to operate and friendly to environment, suitable for large-scale production；There are higher oxygen reduction activity and stability, can be applied in fuel cell.

Description

A kind of preparation method and application of platinum base alloy elctro-catalyst

Technical field

The invention belongs to noble metal electrocatalyst fields, are related to a kind of preparation method of platinum base alloy elctro-catalyst and answer With.

Background technology

Fuel cell is the power generator that the chemical energy with fuel is directly translated into electric energy, since it is followed from Kano The limitation of ring makes it have the advantages of energy conversion efficiency is high, and fuel cell also has environmental-friendly, sustainable power generation, combustion The advantages that material is diversified and higher than energy, therefore it is subject to the extensive concern in the world.Elctro-catalyst is one of fuel cell important Component, at present, the catalyst that Proton Exchange Membrane Fuel Cells uses is mainly platinum and its alloy catalyst, but the valency of platinum Lattice are expensive and reserves in China are relatively low, limit its application in a fuel cell.Therefore, how platinum utilization is improved, The platinum-based electrocatalyst for preparing high activity is the main problem that we study.

In order to reduce the cost of catalyst and improve catalytic efficiency, a most efficient method is exactly using inexpensive transition Metal (Co, Ni, Fe and Cr etc.) forms hud typed catalyst with platinum Pt, and this catalyst can not only change the geometry distribution of Pt (reducing Pt-Pt bond lengths), and relevant electronic structure (such as d electronics vacancy of Pt) can be changed, so as to greatly weaken The combination power of o-o bond and metal-oxygen key advantageously forms and absorbs the intermediate of oxygen to enhance the redox of the catalyst (ORR) it is active.

The patent application document of Publication No. US7053021B1 disclosed a kind of organic synthesis on May 30th, 2006 The method of PtVFe alloys.Pt nucleocapsids prepared by this method not only reduce the content of Pt, and substantially increase ORR catalysis and live Property.The purer Pt/C of its catalytic activity improves 2-4 times.However the method largely uses organic solvent, and it is larger using toxicity 1,2- dihydroxy hexadecanes make reducing agent.Based on the considerations of safety and environmental protection aspect, it is raw that the method is not suitable for high-volume industry Production.Furthermore since introduced inexpensive metal will gradually dissolve in acid solution or fuel cell, cause the stabilization of catalyst Property be deteriorated and interfere its application in Proton Exchange Membrane Fuel Cells.

(STAMENKOVIC V R, MUN B S, ARENZ M, the et al.Trends in such as Stamenkovic Electrocatalysis on Extended and Nanoscale Pt-Bimetallic Alloy Surfaces.Nature Materials,2007,6(3):241-247.) respectively to sputter and anneal under UHV condition Method two kinds of body phase atomic ratios have been made as 3:1 Pt₃M (M=Ni, Co, Fe, Ti, V) polycrystalline.Wherein, sputtering method obtains Alloy most surface Pt atomic ratios are 75%, and the alloy most surface Pt atoms that annealing method obtains are then 100%, and test finds two The activity of person is above polycrystalline Pt.But the process employs electrochemical method synthesis, it is necessary to which special device, is not suitable for big rule Mould produces.

The patent application document of Publication No. US20090098420A1 discloses a kind of fuel electricity on April 16th, 2009 The preparation method of pond catalyst, first with freeze-drying the conditions such as (freeze-dry) and hydrogeneous gaseous mixture 600 DEG C, 800 DEG C or 900 DEG C of high-temperatures reduce to form alloy, then by chemistry and electrochemistry the method for alloy are gone successfully to obtain respectively The Pt of 18wt%Pt and 22wt%Pt series_xCu_y/ C catalyst.The result shows that the elution of Cu can cause carrying for 4 times of electro catalytic activities High and 10 times of high specific activities.But this method of freeze-drying is not suitable for large-scale industrial production.

Present invention employs the methods that heat treatment reduction prepares catalyst, and special preparation facilities, preparation method is not required Simply, it is easy to mass produce.Simultaneously as having carried out pickling to the catalyst of thermal reduction processing, surface is eliminated in acidity The transition metal that can be dissolved in environment, makes surface play the role of roughening, improves catalyst towards oxygen reduction reaction Catalytic activity, there has also been certain raisings for stability.

The content of the invention

It is an object of the invention to propose a kind of preparation method and applications of platinum base alloy elctro-catalyst, this method letter It is single, it is easily controllable, suitable for large-scale production.

The present invention comprises the steps of：

A kind of preparation method of platinum base alloy elctro-catalyst, by platinum carbon catalyst, the alkali of platinum containing amount 30wt%~70wt% Property the substance and mixing of X salting liquids, more than ultrasonic disperse 10min, it is made to be uniformly dispersed to obtain suspension, the X is transition metal； More than the condensing reflux 0.5h at 100-200 DEG C, staticly settles, and removes supernatant, washs to neutrality, vacuum drying；Containing Under the reducing atmosphere of hydrogen, 0.5-3h is heat-treated at 600-800 DEG C, obtains platinum X-alloy carbon compound；Platinum X described in pickling is closed Golden carbon compound is to obtain the platinum base alloy elctro-catalyst.

In the platinum carbon catalyst, X salting liquids, the molar ratio of platinum and X are 1:1.

The alkaline matter is potassium hydroxide, sodium hydroxide, lithium hydroxide, beryllium hydroxide, magnesium hydroxide, hydroxide One or both of strontium, calcium hydroxide, barium hydroxide, ammonium hydroxide, urea are mixed above, adjust the pH=9 of suspension.

The X salt is XF₂、XCl₂、XBr₂、XI₂、X(NO₃)₂Or XSO₄, X is cobalt, nickel, iron or chromium.

The acid pickling step includes：Platinum X-alloy carbon compound is put into 0.5-1M sulfuric acid solution pickling, 60 DEG C~80 DEG C stirring 14h-40h.

The platinum content of the platinum base alloy elctro-catalyst is 40%~70%.

The platinum base alloy elctro-catalyst that the preparation method obtains is applied to fuel cell.

The advantageous effect of technical solution of the present invention includes at least：

The method for the heating condensing reflux that the present invention uses, has not only speeded up the sedimentation of sediment, and has made the hydroxide of X Object is more uniformly distributed what platinum carbon catalyst surface disperseed.

Technical solution of the present invention has finally obtained platinum using the X metals of the chemical method removal platinum alloy superficial layer of pickling Based alloy elctro-catalyst.Acid pickling step is specifically in 60 DEG C~80 DEG C of acid solution, is flowed back using inert gas shielding, is made Standby catalyst has higher performance.

Specific embodiment

Test method in embodiment includes：

Cyclic voltammetry：

Electrolyte：N at room temperature₂The 0.1M HClO of gas saturation₄Aqueous solution, sweep speed 50mV/s, voltage scan range 0.03~1.2V (compared with reversible hydrogen electrode) is taken off using hydrogen and pays areal calculation ECA, and test equipment is collocation rotating disk electrode (r.d.e) System (Pine Instruments, U.S.) CHI730D types electrochemical analyser (CHI Instruments Inc., U.S.).Hydrogen reduction is tested：

Electrolyte：O at room temperature₂The 0.1M HClO of saturation₄Aqueous solution, rotating circular disk rotating speed 1600rpm, forward scan 10mV/s, voltage scan range are 0.2~1V (compared with reversible hydrogen electrode), and test equipment is collocation rotating disk electrode (r.d.e) system The CHI730D types electrochemical analyser (CHI Instruments Inc., U.S.) of (Pine Instruments, U.S.).

Stability test：

Electrolyte：N₂The 0.1M HClO of gas saturation₄Aqueous solution, sweep speed 50mV/s, voltage scan range 0.6~ 1.2V (compared with reversible hydrogen electrode), 500 circle of room temperature scanning, test equipment are collocation rotating disk electrode (r.d.e) system (Pine Instruments, U.S.) CHI730D types electrochemical analyser (CHI Instruments Inc., U.S.).

Embodiment 1：

10mL deionized waters are added in beaker, then by 0.0746g Co (NO₃)₂·6H₂O is added in beaker, stirring Uniformly, 0.1g 50wt%Pt/C, ultrasonic 30min are added in, adds in by volume 1:4 diluted concentrated ammonia liquors, adjust pH=9,110 DEG C condensing reflux 2h, staticly settles, removes supernatant, then centrifuge sediment, and drying is dried in vacuo at 60 DEG C.Then In 600 DEG C, 10%H₂Thermal reduction processing 3h, cooled to room temperature under/Ar atmosphere.By obtained catalyst and 30mL, 1mol/ The H of L₂SO₄Solution mixes, then ultrasonic 30min is stirred for 24 hours in 80 DEG C of oil baths.It then centrifuges, washs for several times, 60 DEG C Lower vacuum drying drying.

After carrying out cyclic voltammetry to the platinum cobalt alloy carbon particle catalyst, the platinum carbon particle catalyst is obtained Electrochemical surface area be 53m²/g Pt；

After carrying out hydrogen reduction test to the platinum cobalt alloy carbon particle catalyst, the platinum carbon particle catalyst hydrogen reduction is obtained The mass activity of reaction is 273mA/mg Pt；

After carrying out stability test to the platinum cobalt alloy carbon particle catalyst, the electrification of the platinum carbon particle catalyst is obtained It learns surface area losses and falls to 27% for the 15%, mass activity of oxygen reduction reaction.

Embodiment 2：

Operating process is, in the present embodiment, the type of X salt is cobalt chloride with embodiment 1 different from 1 part of embodiment (CoCl₂)。

In the present embodiment, CoCl₂Addition be 0.0333g.

After carrying out cyclic voltammetry to the platinum cobalt alloy carbon particle catalyst, the platinum carbon particle catalyst is obtained Electrochemical surface area be 47m²/g Pt；

After carrying out hydrogen reduction test to the platinum cobalt alloy carbon particle catalyst, the platinum carbon particle catalyst hydrogen reduction is obtained The mass activity of reaction is 271mA/mg Pt；

After carrying out stability test to the platinum cobalt alloy carbon particle catalyst, the electrification of the platinum carbon particle catalyst is obtained It learns surface area losses and falls to 26% for the 16%, mass activity of oxygen reduction reaction.

Embodiment 3：

Operating process is, in the present embodiment, the type of X salt is nickel chloride with embodiment 1 different from 1 part of embodiment (NiCl₂)。

In the present embodiment, NiCl₂Addition is 0.0332g.

After carrying out cyclic voltammetry to the platinum-nickel alloy carbon particle catalyst, the platinum carbon particle catalyst is obtained Electrochemical surface area be 48m²/g Pt；

After carrying out hydrogen reduction test to the platinum-nickel alloy carbon particle catalyst, the platinum carbon particle catalyst hydrogen reduction is obtained The mass activity of reaction is 266mA/mg Pt；

After carrying out stability test to the platinum-nickel alloy carbon particle catalyst, the electrification of the platinum carbon particle catalyst is obtained It learns surface area losses and falls to 25% for the 15%, mass activity of oxygen reduction reaction.

Embodiment 4：

Operating process is that alkaline matter used is in the present embodiment with embodiment 1 different from 1 part of embodiment The aqueous solution of 0.05M potassium hydroxide.

After carrying out cyclic voltammetry to the platinum cobalt alloy carbon particle catalyst, the platinum carbon particle catalyst is obtained Electrochemical surface area be 40m²/g Pt；

After carrying out hydrogen reduction test to the platinum cobalt alloy carbon particle catalyst, the platinum carbon particle catalyst hydrogen reduction is obtained The mass activity of reaction is 247mA/mg Pt；

After carrying out stability test to the platinum cobalt alloy carbon particle catalyst, the electrification of the platinum carbon particle catalyst is obtained It learns surface area losses and falls to 31% for the 28%, mass activity of oxygen reduction reaction.

Embodiment 5：

Operating process is that the condition of condensing reflux is 120 in the present embodiment with embodiment 1 different from 1 part of embodiment DEG C condensing reflux 2h.

After carrying out cyclic voltammetry to the platinum cobalt alloy carbon particle catalyst, the platinum carbon particle catalyst is obtained Electrochemical surface area be 48m²/g Pt；

After carrying out hydrogen reduction test to the platinum cobalt alloy carbon particle catalyst, the platinum carbon particle catalyst hydrogen reduction is obtained The mass activity of reaction is 269mA/mg Pt；

After carrying out stability test to the platinum cobalt alloy carbon particle catalyst, the electrification of the platinum carbon particle catalyst is obtained It learns surface area losses and falls to 26% for the 16%, mass activity of oxygen reduction reaction.

Embodiment 6：

Operating process is that the condition of condensing reflux is 160 in the present embodiment with embodiment 1 different from 1 part of embodiment DEG C condensing reflux 1h.

After carrying out cyclic voltammetry to the platinum cobalt alloy carbon particle catalyst, the platinum carbon particle catalyst is obtained Electrochemical surface area be 40m²/g Pt；

After carrying out hydrogen reduction test to the platinum cobalt alloy carbon particle catalyst, the platinum carbon particle catalyst hydrogen reduction is obtained The mass activity of reaction is 241mA/mg Pt；

After carrying out stability test to the platinum cobalt alloy carbon particle catalyst, the electrification of the platinum carbon particle catalyst is obtained It learns surface area losses and falls to 23% for the 15%, mass activity of oxygen reduction reaction.

Embodiment 7：

Operating process is different from 1 part of embodiment with embodiment 1, the present embodiment when carrying out heat-treatment alloying, Heat treatment condition is 700 DEG C, 5%H₂Thermal reduction processing 2h under/Ar atmosphere.

After carrying out cyclic voltammetry to the platinum cobalt alloy carbon particle catalyst, the platinum carbon particle catalyst is obtained Electrochemical surface area be 46m²/g Pt；

After carrying out hydrogen reduction test to the platinum cobalt alloy carbon particle catalyst, the platinum carbon particle catalyst hydrogen reduction is obtained The mass activity of reaction is 260mA/mg Pt；

After carrying out stability test to the platinum cobalt alloy carbon particle catalyst, the electrification of the platinum carbon particle catalyst is obtained It learns surface area losses and falls to 23% for the 14%, mass activity of oxygen reduction reaction.

Embodiment 8：

Operating process is different from 1 part of embodiment with embodiment 1, the present embodiment when carrying out heat-treatment alloying, Heat treatment condition is 800 DEG C, 5%H₂Thermal reduction processing 1h under/Ar atmosphere.

After carrying out cyclic voltammetry to the platinum cobalt alloy carbon particle catalyst, the platinum carbon particle catalyst is obtained Electrochemical surface area be 43m²/g Pt；

After carrying out hydrogen reduction test to the platinum cobalt alloy carbon particle catalyst, the platinum carbon particle catalyst hydrogen reduction is obtained The mass activity of reaction is 250mA/mg Pt；

After carrying out stability test to the platinum cobalt alloy carbon particle catalyst, the electrification of the platinum carbon particle catalyst is obtained It learns surface area losses and falls to 22% for the 12%, mass activity of oxygen reduction reaction.

Embodiment 9：

Operating process is that the Pt/C used in the present embodiment is 70wt%Pt/ with embodiment 1 different from 1 part of embodiment C, the Co (NO of addition₃)₂·6H₂The amount of O is 0.104g, other preparation process can refer to embodiment one.

After carrying out cyclic voltammetry to the platinum cobalt alloy carbon particle catalyst, the platinum carbon particle catalyst is obtained Electrochemical surface area be 34m²/g Pt；

After carrying out hydrogen reduction test to the platinum cobalt alloy carbon particle catalyst, the platinum carbon particle catalyst hydrogen reduction is obtained The mass activity of reaction is 184mA/mg Pt；

After carrying out stability test to the platinum cobalt alloy carbon particle catalyst, the electrification of the platinum carbon particle catalyst is obtained It learns surface area losses and falls to 22% for the 8%, mass activity of oxygen reduction reaction.

Comparative example 1：

Operating process is that the condition of condensing reflux is 50 in the present embodiment with embodiment 1 different from 1 part of embodiment DEG C condensing reflux is for 24 hours.

After carrying out cyclic voltammetry to the platinum cobalt alloy carbon particle catalyst, the platinum carbon particle catalyst is obtained Electrochemical surface area be 38m²/g Pt；

After carrying out hydrogen reduction test to the platinum cobalt alloy carbon particle catalyst, the platinum carbon particle catalyst hydrogen reduction is obtained The mass activity of reaction is 160mA/mg Pt；

After carrying out stability test to the platinum cobalt alloy carbon particle catalyst, the electrification of the platinum carbon particle catalyst is obtained It learns surface area losses and falls to 29% for the 17%, mass activity of oxygen reduction reaction.

Comparative example 2：

Operating process is that the condition of condensing reflux is 80 in the present embodiment with embodiment 1 different from 1 part of embodiment DEG C condensing reflux 12h.

After carrying out cyclic voltammetry to the platinum cobalt alloy carbon particle catalyst, the platinum carbon particle catalyst is obtained Electrochemical surface area be 40m²/g Pt；

After carrying out hydrogen reduction test to the platinum cobalt alloy carbon particle catalyst, the platinum carbon particle catalyst hydrogen reduction is obtained The mass activity of reaction is 208mA/mg Pt；

After carrying out stability test to the platinum cobalt alloy carbon particle catalyst, the electrification of the platinum carbon particle catalyst is obtained It learns surface area losses and falls to 26% for the 14%, mass activity of oxygen reduction reaction.

It is understood based on above-described embodiment, the inexpensive transition metal such as cobalt is added in platinum carbon catalyst, go to close by pickling The platinum cobalt alloy elctro-catalyst that golden step is formed has very high electro catalytic activity, initial redox reaction (ORR) activity 273mA/mg Pt and 53m can be reached respectively with initial electrochemical surface area²/g Pt.According to the application preparation method institute The platinum alloy C catalyst being prepared possesses higher platinum content.

Claims (7)

1. a kind of preparation method of platinum base alloy elctro-catalyst, which is characterized in that by the platinum carbon of platinum containing amount 30wt%~70wt% Catalyst, alkaline matter and the mixing of X salting liquids, more than ultrasonic disperse 10min make it be uniformly dispersed to obtain suspension, and the X is Transition metal；More than the condensing reflux 0.5h at 100-200 DEG C, staticly settles, and removes supernatant, washs to neutrality, vacuum is done It is dry；Under the reducing atmosphere containing hydrogen, 0.5-3h is heat-treated at 600-800 DEG C, obtains platinum X-alloy carbon compound；Pickling The platinum X-alloy carbon compound is to obtain the platinum base alloy elctro-catalyst.

2. preparation method according to claim 1, which is characterized in that in the platinum carbon catalyst, X salting liquids, platinum and X Molar ratio be 1:1.

3. preparation method according to claim 1, which is characterized in that the alkaline matter is potassium hydroxide, hydroxide One kind in sodium, lithium hydroxide, beryllium hydroxide, magnesium hydroxide, strontium hydroxide, calcium hydroxide, barium hydroxide, ammonium hydroxide, urea or Two or more mixing adjust the pH=9 of suspension.

4. preparation method according to claim 1, which is characterized in that the X salt is XF₂、XCl₂、XBr₂、XI₂、X (NO₃)₂Or XSO₄, X is cobalt, nickel, iron or chromium.

5. preparation method according to claim 1, which is characterized in that acid pickling step includes：

Platinum X-alloy carbon compound is put into the aqueous solution pickling of 0.5-1M sulfuric acid, 14h-40h is stirred at 60 DEG C~80 DEG C.

6. preparation method according to claim 1, which is characterized in that the platinum content of the platinum base alloy elctro-catalyst is 40%~70%.

7. the platinum base alloy elctro-catalyst that preparation method described in claim 1 obtains is applied to fuel cell.