PL230151B1 - Integrated, miniature mass spectrometer - Google Patents

Description

Description of the invention

The subject of the invention is an integrated, miniature mass spectrometer made with the use of MEMS techniques, designed for high-precision analysis of the chemical composition of various substances by operating at high vacuum, of the order of 10 ^-5 -10 ^-7 hPa.

Mass spectrometers make it possible to analyze the chemical composition of various substances. The test begins with dosing and ionizing the test sample. Then, using an electric or magnetic field, the ions produced are separated based on their mass to charge ratio. Finally, the detector counts the separated ions and the result is obtained in the form of a mass spectrum. Mass spectrometers are vacuum devices (ion separation, and in some solutions also ionization, takes place under reduced pressure), therefore these devices must be permanently connected to the pumping systems.

The mass spectrometer can analyze substances in any state of aggregation - solid, liquid and gaseous, which results in the wide application of this measurement technique. It is used to identify chemical compounds and their mixtures, to determine their structure, elemental composition and isotopic composition (determining the source of origin), and in particular to precisely determine the composition of complex compounds with low molar masses (proteomics, metabolomics, material research and polymer chemistry) .

In recent years, numerous attempts have been made to miniaturize mass spectrometers and / or their components. The goal is to create portable analytical devices that can be used not only in specialized laboratories. Reducing the dimensions will expand the scope of their applications in previously unavailable scientific, civil and military solutions. In the miniaturization process, in addition to precision mechanics techniques, microelectronic and microengineering MEMS techniques are used. In the latter technique, the basic materials are monocrystalline silicon and borosilicate glass. Most of the literature and patent reports concern the miniaturization of individual SM components, few of the systems consist of several components.

From the publication of S. Sheridan, M.W. Bardwell, A.D. Morse, G.H. Morgan, A carbon nano tube electron impact ionization source for low-power, compact spacecraft mass spectrometers, Advances in Space Research vol. 49, no. 8 (2012) 1245-1252, the structure of an ion source using half electron emission from carbon nanotubes is known. The device is designed to ionize the tested sample by bombarding gas particles with emitted high-energy electrons.

From the publication of L.F. Velasquez-Garcia, B.L.P. Gassend and A.I. Akinwande, CNT-based MEMS / NEMS gas ionizers for portable mass spectrometry applications, Journal of Microelectromechanical Systems vol. 19, no. 3 (2010) 484-493 there is a known miniature gas ionizer operating on a similar principle, but entirely manufactured by MEMS techniques.

From CM Tassetti, R. Mahieu, JS Danel et al., A MEMS electron impact ion source integrated in a microtime-of-flight mass spectrometer, Sensors and Actuators B vol. 189 (2013) 173-178, a miniature ion source is known. integrated with a time-of-flight analyzer. The structure uses an external source of electrons in the form of a tungsten filament, electrons are introduced into the ionization chamber, from where the generated ions are fed towards the mass analyzer.

From the publication of K.H. Gilchrist, C.A. Bower, M.R. Lueck et al., A novel ion source and detector for a miniature mass spectrometer, Proc. IEEE Sensors Conf. (Atlanta, GA, 28-31 October 2007) 1372-1375, a Wien filter made with MEMS techniques using perpendicular ion mass analysis is known electric and magnetic fields deflecting accelerated ions. The detector is made in the form of a matrix of silicon electrodes.

From the publication of M. Geear, R.R.A. Syms, S. Wright, and A.S. Holmes, Monolithic MEMS quadrupole mass spectrometers by deep silicon etching, Journal of Microelectromechanical Systems, vol. 14, no. 5 (2005) 1156-1166, there is a known miniature quadrupole filter made by MEMS techniques and by methods of precision mechanics. Four metal filter rods with a diameter of 250 μm are mounted on interconnected silicon substrates, which are used for precise positioning.

From the publication of K. Cheung, L.F. Velaquez-Garcia and A.I. Akinwande, Chip-scale quadrupole mass filters for portable mass spectrometry, Journal of Microelectromechanical Systems vol. 19, no. 3 (2010) 469-483, a quadrupole filter with non-hyperbolic silicon electrodes is known.

From the publication of J.P. Haushild, E. Wapelhorst, J. Muller, Mass spectra measured by a fully integrated MEMS spectrometer, International Journal of Mass Spectrometry vol. 264, no. 1 (2007) 53-60, the integrated structure of a miniature mass spectrometer produced by MEMS techniques from glass is known

PL 230 151 B1 and silicon. Integrated on one substrate: ionizer, ion separator and detector. Gaseous samples are fed through glass capillaries glued to the structure.

From the publication of I. Chakraborta, W.C. Tang, D.P. Barne, T.K. Tang, MEMS micro-valve for space applications, Sensors and Actuators vol, 83, no. 1-3 (2000) 188-193, a miniature vacuum valve is known in the form of a silicon diaphragm which closes the valve by means of a piezoelectric actuator.

From the publication of B.G. Jamieson, B.A. Lynch, D.N. Harpold et al., Microfabricated silicon leak for sampling planetary atmospheres with a mass spectrometer, Review of Scientific Instruments vol. 78, no. 6 (2007) 065109, a gas dispenser operating on the principle of a micro-stain gland is known. It is made of two silicon substrates joined together by fusion bonding. A 1 gm wide channel was etched in the first substrate and the lead holes in the second.

From the international patent application WO2007055756 there is known a MEMS mass spectrometer with metal walls between the cover and the base, the walls defining a series of internal chambers, successively a sample gas input chamber, an ionizer chamber, a number of optically lensing ion beam chambers and ion separation chambers. At the end of the ion separation chamber is a detector array which includes a plurality of V-shaped detector elements positioned along two parallel lines and arranged to capture all the ionized beams produced by the mass spectrometer. The structure described also has diaphragm micropumps connected in parallel to each of the cells. The device was made using spray-free soldering, the main components forming the structure are produced in the LIGA process, and the materials used are Au, SiO2, poly-Si. The proposed manufacturing technology allows to maintain a vacuum of a maximum of 1 e-2 mbar.

A common feature of the solutions described in the prior art is that the vacuum atmosphere necessary to obtain high resolution in mass spectrometers is generated by external, relatively large pumping systems, and even if they are integrated, they do not provide the high or ultrahigh vacuum necessary for mass spectrometers. obtaining an acceptable accuracy of the analysis.

In the patent application P408322 by T. Grzebyk, A. Górecka-Drzazga, and J. Dziuban, a micromechanical, ion-sorption vacuum pump is described. The pump is technologically consistent with other MEMS microsystems, has a multi-layer structure and consists of silicon and glass. In the micropump, the gas is ionized by means of an electron beam emitted from a field electron source, and the ionized particles are absorbed on / in the titanium getter layer. The micropump enables the creation of a vacuum of 10 ^-5 hPa.

From the article by T. Grzebyk, A. Górecka-Drzazga, and J. Dziuban, "Glow-discharge ionsorption micropump for vacuum MEMS", Sensors and Actuators A vol. 208 (2014) 113-119, a vacuum micropump is known, which consists of consists of two cathodes and an anode separated by two glass spacers and two magnets on both sides of the micropump. In the micropump, the gas is ionized by means of an electric discharge. The micropump enables the creation of a vacuum at the level of 10 ^-7 hPa.

The essence of the integrated miniature mass spectrometer according to the invention, made by MEMS techniques in the form of a sandwich with the use of silicon and glass, sealed with the use of vacuum anode bonding containing a vacuum micropump, consisting of two opposite cathodes and an anode placed in the middle separated by two glass spacers; gas dispenser and ionizer, ion separator and detector, consists in the fact that it has a glass substrate common to all elements and glass covers, upper and lower, connected to the glass substrate and mutually sealed with a silicon frame as one chip, with the substrate and covers made of there are partial etchings or through holes, which distinguish subsequent chambers and areas: micropump chamber, dispenser area, gas ionizer chamber, ion separator chamber and detector area, while in the micropump chamber the glass substrate is connected to the upper surface with a silicon anode and the anode with top cover, which, together with the anode and the substrate, have concentric through holes, creating a space closed on both sides with micropump cathodes; a first microchannel is provided between the micropump chamber and the gas ionizer chamber in the glass substrate; in the gas ionizer chamber, the glass substrate is connected with the upper surface with the gate and the gate with the top cover, the lower surface with the glass substrate connected with the repulsive electrode and the repulsive electrode with the bottom cover, in this chamber the upper and lower cover, gate, glass substrate and electrode repulsive, they have concentric through holes creating space

The ionizer cathode is closed at the top with a layer of emission material applied, and the ionizer anode at the bottom, and the microchannel of the dispenser connects to the ionizer chamber; then a second microchannel is made in the glass substrate between the ionizer chamber and the separator chamber; in the separator chamber, a set of introducing electrodes and measuring electrodes running symmetrically along the chamber are connected to the glass substrate with a longitudinal separator channel, and at the end of the separator chamber there is a detector in the form of at least one electrode attached to at least the upper surface of the glass substrate, through which the glass substrate connects to the top or bottom cover. Preferably the layer of emissive material is in the form of carbon nanotubes.

Preferably, the distance between the ionizer cathode and the gate is 0.3 mm to 1.1 mm, and the space bounded by these electrodes is the electron emission region.

Preferably, the distance between the ionizer gate, the ion-repelling electrode and the anode is 1.1 mm each, and the space delimited by these electrodes constitutes the ionization region.

Preferably, in the ionizer chamber, the openings in the gate, the ion-repelling electrode, and in the top, bottom, and glass substrate are square with a width of 1 to 4 mm.

Preferably, the microchannel of the dispenser is etched in a silicon frame and is equipped with a valve in the form of a piezoelectric actuator.

Preferably, the micropump and ionizer cathodes are held at ground potential, the micropump anode is positively biased from 500V to 1000V, the ionizer anode is positively biased from 800V to 1800V, and the gate has a potential of 500V to 800V.

Preferably, a magnetic field of 0.1 to 0.3 T runs in the cathode-anode direction in the ionizer chamber.

Preferably, the introducing electrode assembly consists of at least two pairs of introducing electrodes in the form of silicon microcantilevers, each successive pair being polarized to the previous one, and the potential difference is between 100 and 200 V.

Preferably, the introducing electrode assembly is distant from the center of the ionization chamber from 1 to 8 mm.

In a variant of the invention, the separator channel is an elongated, through hole, and the upper and lower pair of electrodes of the introducing electrodes in the form of microcantilever and the upper and lower pair of electrically connected measuring electrodes are connected to the upper and lower surfaces of the glass substrate symmetrically with respect to the axis running along the center of the chamber. , constituting a quadrupole analyzer, and at the end of the separator chamber, a pair of detector electrodes is attached to the upper and lower surfaces of the glass substrate, with the working surfaces of all electrodes in this chamber overlapping the surface of the separator channel, and further, through the detector electrodes, the glass substrate is connected to the upper cover and lower, closing the separator chamber.

Preferably, the electrical connection of the measuring electrodes consists in pairing the measuring electrodes in pairs, the upper left with the lower right, and the upper right with the lower left.

Preferably, the thickness of the glass substrate is from 0.7 to 2.0 mm.

Preferably, the horizontal distances between the measurement electrodes within the upper and lower pairs are 50-90% of the thickness of the glass substrate.

In a further variant of the invention, the separator channel is an elongated recess, and symmetrically with respect to the axis of the separator channel, a pair of introducing electrodes is connected to the upper surface of the substrate, followed by the first pair of forming electrodes, and at the end of the chamber, a second pair of forming electrodes and a single detector electrode. the surface of the introducing electrodes and the detector electrodes overlap with the surface of the separator channel.

Preferably, the introducing electrodes and the forming electrodes are made in the form of 0.5 mm wide silicon microconvulses.

Preferably, the separator channel being the ion drift region is 20 mm to 35 mm long.

In a further variant of the invention, the separator channel is an elongated recess, and symmetrically with respect to the axis of the separator channel, a pair of electrodes of the introducing electrodes is connected to the upper surface of the substrate, and then a pair of compensating electrodes, made in the form of parallel, elongated rectangles, and at the end of the chamber, a pair of aperture electrodes in in the form of microcantilevers and a single detector electrode, the surface of the introducing electrodes, compensating electrodes as well as the aperture and detector electrodes overlapping the surface of the separator channel, and between the compensating electrodes there is a voltage of 20 V to 300 V preventing twisting of the ions being shot as a result of the magnetic field.

PL 230 151 B1

Preferably, a magnetic field of 0.1 to 0.8 T prevails in the separator chamber perpendicular to its surface.

The advantages of the invention are the small dimensions of the device and the possibility of using the mass spectrometer anywhere, not only in specialized laboratories. The use of MEMS techniques for the production of the spectrometer will allow for large-scale production, eliminating the need for an external vacuum housing. The integration of the spectrometer with a vacuum micropump extends the time of the correct operation of the electron source and the mass analyzer, reduces aging effects and allows for better ion mass separation parameters, and thus a better separation resolution. Mass spectrometers are used in many fields of science. However, these are large and expensive devices. The reduction in size makes such devices portable and reduces power consumption and costs.

The invention is presented in more detail in the examples and based on the drawing, Fig. 1 shows the idea of the construction of an integrated, miniature mass spectrometer, Fig. 2 shows the structure of the ionizer chamber, Fig. 3 shows a variant of the mass separator with a quadrupole filter, Fig. 4 shows a variant of the separator masses with a TOF filter, Fig. 5 shows a variant of the mass separator with an electromagnetic filter, while Fig. 6 shows a general view and a cross-section of the spectrometer in a variant with a quadrupole filter.

P r z k ł a d 1

The integrated, miniature mass spectrometer, made by MEMS techniques in the form of a sandwich with the use of silicon and glass, sealed with the use of vacuum anodic bonding, contains a vacuum micropump, consisting of two opposite cathodes and placed in the middle of the anode separated by two glass spacers, built according to the invention P408322 described in the condition techniques; gas dispenser and ionizer, ion separator and detector, characterized by the fact that it has a glass substrate 6 common to all elements and glass covers, upper 7a and lower 7b, connected to the glass substrate 6 and mutually sealed with a silicon frame 8 as one chip, partial etchings or through holes are made in the glass substrate 6 and the covers 7a, 7b, which distinguish further chambers and areas: micro pump chamber 5, dispenser 1 area, gas ionizer chamber 2, ion separator chamber 3 and detector area 4 In the micropump chamber 5, the glass substrate 6 is connected by its upper surface to the silicon anode of the micropump 25 and the anode of the micropump 25 to the upper cover 7a, which, together with the anode of the micropump 25 and the glass substrate 6, have concentric through holes, creating a space closed on both sides by the cathodes of the micropump 24. a first microchannel 9a is made with a micropump chamber 5 and a gas ionizer chamber 2 in a glass substrate 6. The gas ionizer 2 is a multi-layer silicon-glass structure. In the gas ionizer chamber 2, the glass substrate 6 is connected by its upper surface to the ionizer gate 14 and the gate 14 to the top cover 7a, the lower surface to the glass substrate 6 to the repulsive electrode 16 and the repulsive electrode 16 to the bottom cover 7b, in this cover chamber the upper 7a and lower 7b, the gate 14, the glass substrate 6 and the repulsive electrode 16 have concentric through holes creating a space closed at the top by the ionizer cathode 12 with a layer of emissive material 13 in the form of carbon nanotubes with dimensions of 3 x 3 mm ² , and at the bottom with an anode of the ionizer 15. The microchannel of the dispenser 1, etched in the form of self-melting V-shaped grooves 5 μm wide in the form of serpentines with a total length of 5 cm, joins the ionizer chamber 2. The distance between the cathode of the ionizer 12 and the gate 14 is 0.7 mm, and the space bounded by these electrodes is the electron emission area 10. The gap between the ionizer gate 14, the ion-repelling electrode 16 and the anode of the ionizer 15 is 1.1 mm, and the space is limited. with these electrodes is the ionization region 11. The openings in the gate 14, the ion-repelling electrode 16 and in the top 7a, bottom 7b and glass substrate 6 are 2.5 mm square. The microchannel of the dispenser 1 is etched in the silicon frame 8 and is equipped with a valve in the form of a piezoelectric actuator. A second microchannel 9b is provided in the glass substrate 6 between the ionizer chamber 2 and the separator chamber 3. In the separator chamber 3, the glass substrate 6 has a separator channel 20 being an elongated through hole, 4 mm wide and 5 mm deep, constituting the drift area, and a set of electrodes connected to the upper and lower surfaces of the glass substrate 6 symmetrically with respect to the axis running along the center of the chamber. insertion electrodes 17, consisting of two upper and two lower pairs of introducing electrodes in the form of microcantilevers and an upper and lower pair of measuring electrodes 18 constituting a quadrupole analyzer, each 0.4 mm thick, 3 mm wide, 30 mm long. The lead-in electrode assembly 17 is 4 mm from the center of the ionization chamber. At the end of the separator channel 20, a pair of detector electrodes 4 is attached to the upper and lower surfaces of the glass substrate 6,

6 mm wide and 3 mm long, the working surfaces of all electrodes 17, 18, 4 in this chamber overlap the surface of the separator channel 20. The glass substrate 6 is connected to the top 7a and bottom 7b through the detector electrodes 4, closing the separator chamber 3. A silicon frame 8, 0.4 mm thick and 3 mm wide, runs around the entire spectrometer, sealing all chambers. The measuring electrodes 18 are electrically connected to each other in pairs, the upper left with the lower right and the upper right with the lower left. An ion trapping area 19 is formed concentrically between the measuring electrodes. The thickness of the glass substrate 6 is 1.1 mm. The horizontal distances between the measuring electrodes 18 in the upper and lower pairs constitute 70% of the thickness of the glass substrate 6. The cathodes of the micropump 24 and the ionizer 12 are kept at the ground potential, the anode of the micropump 25 is polarized with a positive voltage of 700 V and the anode of the ionizer 15 is polarized with the positive voltage. 1300 V, and the gate 14 has a potential of 600 V. In the ionizer chamber 2 in the cathode-anode direction runs a magnetic field of 0.2 T. In the set of introducing electrodes 17, each successive upper and lower pair is polarized in relation to the previous upper and lower pairs introducing electrode pair, the first upper and lower pair of electrodes having a voltage of 0 V, and a voltage of 100 V on the second upper and lower pair of electrodes, thanks to which the tested particles are accelerated and lensed in the separator chamber 2.

P r z k ł a d 2

Spectrometer made as in example 1, with the difference that the separator channel 20 is an elongated recess, and symmetrically with respect to the axis of the separator channel 20, a set of introducing electrodes 17 consisting of two pairs is connected to the upper surface of the substrate, followed immediately by the first pair of forming electrodes. 21 and at the end of the chamber, a second pair of forming electrodes 21 and a single detector electrode 4, the surface of the introducing electrodes 17 and detector electrodes 4 overlapping the surface of the separator channel 20 constituting the drift region. The introducing electrodes 17 and the forming electrodes 21 are made in the form of 0.5 mm wide silicon microconvulses. The separator channel 20 being the ion drift region has a length of 25 mm.

P r z k ł a d 3

Spectrometer made as in example 1, with the difference that the separator channel 20 being the drift zone is in the form of an elongated cavity, and symmetrically with respect to the axis of the separator channel 20, a set of introducing electrodes 17 consisting of two pairs is connected to the upper surface of the glass substrate 6, and then a pair of compensating electrodes 22, made in the form of parallel, elongated rectangles, and at the end of the separator chamber 3, a pair of 0.2 mm wide aperture electrodes 23 in the form of microcantilever and a single detector electrode 4, the surface of introducing electrodes 17, compensating electrodes 22 and the aperture electrodes 23 and detector electrodes 4 overlap the surface of the separator channel 20. For ions with a mass-to-charge ratio m / z = 40, the magnetic field in the separator chamber 3 generated by neodymium magnets located above and below the drift area is 0.18 T and runs perpendicular to its surface, a compensating voltage of 130 V against torsion shot ions as a result of the magnetic field.

The operation of the spectrometer according to the invention is as follows: before starting the spectrometer, a micropump is turned on, which pumps the internal volume of the entire system (ionization and separation chamber) to a high vacuum (preferably 10 ^-5 hPa). Then the feeder channel is opened and the tested gas sample slowly enters inside. The gas is ionized in the ionizer module by an electron beam emitted from the field cathode under the influence of a strong electric field. The generated electrons are captured by the anode and the ionized gas is introduced through the electrode array into the mass analyzer chamber, where the ions are separated and detected. Separation uses the charge and mass (m / z ratio) of the ions under study, which interact with an electric or magnetic field. In the time-of-flight analyzer of the ion beam, a pulse accelerating ions is used, introducing them into the region of free drift, where they separate into fractions of different m / z, lighter ions reach the detector faster than heavier ions. In the quadrupole ion trap mass filter and the Wien filter using crossed electric and magnetic fields, only ions with a given m / z have a stable passage through the drift area, the rest is captured by the filter electrodes.

Claims (19)

1. Integrated miniature mass spectrometer made by MEMS techniques in the form of a sandwich with the use of silicon and glass, sealed by vacuum anode bonding, containing a vacuum micropump, consisting of two opposite cathodes and placed in the middle of the anode separated by two glass spacers; gas dispenser and ionizer, ion separator and detector, characterized in that it has a glass substrate (6) common to all elements and glass covers, upper (7a) and lower (7b), connected to the glass substrate (6) and sealed with a silicon frame (8) as one chip, with partial etchings or through holes in the glass substrate (6) and covers (7a), (7b), which distinguish subsequent chambers and areas: micropump chamber (5), dispenser area ( 1), gas ionizer chamber (2), ion separator chamber (3) and detector area (4), where in the micropump chamber (5) the glass substrate (6) is connected with the silicon anode of the micropump (25) and the anode of the micropump (25) with a top cover (7a) which, together with the anode of the micropump (25) and the glass substrate (6), have concentric through holes, creating a space closed on both sides by cathodes of the micropump (24); a first microchannel (9a) is provided in the glass substrate (6) between the micropump chamber (5) and the gas ionizer chamber (2); in the gas ionizer chamber (2), the glass substrate (6) is connected with the upper surface with the gate (14) and the gate with the upper cover (7a), the lower surface with the glass substrate (6) is connected with the repulsive electrode (16) and the repulsive electrode with the cover lower (7b), while in this chamber of the cover the upper (7a) and lower (7b), the gate (14), the glass substrate (6) and the repulsive electrode (16) have concentric through holes forming a space closed at the top with the ionizer cathode (12) ) with a layer of emission material (13) applied, and from the bottom with an ionizer anode (15), a microchannel of the dispenser (1) connects to the ionizer chamber (2); then a second microchannel (9b) is made in the glass substrate (6) between the ionizer chamber (2) and the separator chamber (3); in the separator chamber (3), a set of introducing electrodes (17) and silicon electrodes are connected to the glass substrate (6), which has a longitudinal separator channel (20), running along the chamber and symmetrically to its axis, and at the end of the separator chamber (3) there is a detector (4) in the form of at least one electrode attached to at least the upper surface of the glass substrate (6) through which the glass substrate (6) connects to the upper (7a) or lower (7b) cover. 2. Spectrometer according to claim The method of claim 1, characterized in that the layer of the emitting material (13) is in the form of carbon nanotubes. 3. Spectrometer according to claim The method of claim 1, characterized in that the distance between the cathode of the ionizer (12) and the gate (14) is from 0.3 mm to 1.1 mm, and the space bounded by these electrodes constitutes the electron emission area (10). 4. Spectrometer according to claim The method of claim 1, characterized in that the distance between the ionizer gate (14), the ion-repelling electrode (16) and the anode of the ionizer (15) is 1.1 mm each, and the space delimited by these electrodes constitutes the ionization region (11). 5. Spectrometer according to claim 1 The method of claim 1, characterized in that in the ionizer chamber the openings in the gate (14), the ion-repelling electrode (16) and in the top (7a), bottom (7b) covers and the glass substrate are square with a width of 1 to 4 mm. 6. Spectrometer according to claim The method of claim 1, characterized in that the microchannel of the dispenser (1) is etched in the silicon frame (8) and is provided with a valve in the form of a piezoelectric actuator. 7. Spectrometer according to claim The method of claim 1, characterized in that the cathodes of the micropump (24) and the ionizer (12) are kept at the ground potential, the anode of the micropump (25) is polarized with a positive voltage from 500 V to 1000 V, the anode of the ionizer (15) is polarized with a positive voltage of 800 V to 1800 V, and the gate (14) has a potential of 500 V to 800 V. 8. A spectrometer according to claim A magnetic field of 0.1 to 0.3 T runs in the ionizer chamber (2) in the cathode-anode direction. PL 230 151 B1 9. Spectrometer according to claim 1 The method according to claim 1, characterized in that the set of introducing electrodes (17) consists of at least two pairs of introducing electrodes in the form of silicon microcantilever, each pair being polarized in relation to the previous one. 10. Spectrometer according to claim 1 The method of claim 1, characterized in that the assembly of introducing electrodes (17) is distant from the center of the ionizer chamber (2) from 1 mm to 8 mm. 11. A spectrometer according to claim 1 3. The separator channel (20) is an elongated through hole, constituting the drift zone, and a set of introducing electrodes (20) is attached to the upper and lower surfaces of the glass substrate (6) symmetrically with respect to the axis running along the center of the separator channel (20). 17) in the form of at least two upper and lower pairs of introducing electrodes in the form of microcantilever and an upper and lower pair of measuring electrodes (18), electrically connected, constituting a quadrupole analyzer, and at the end of the separator chamber (3) to the upper and lower surface of the glass substrate ( 6), a pair of detector electrodes (4) is connected, with the working surfaces of all electrodes in this chamber overlapping the surface of the separator channel (20), and, moreover, through the detector electrodes (4), the glass substrate (6) is connected to the top cover (7a) and lower (7b), closing the separator chamber (3). 12. Spectrometer according to claim 1, 11. The method according to claim 11, characterized in that the electrical connection of the measuring electrodes (18) consists in connecting the measuring electrodes in pairs: the upper left with the lower right and the upper right with the lower left. 13. A spectrometer according to claim 1, The method of claim 11, characterized in that the thickness of the glass substrate (6) is between 0.7 and 2.0 mm. 14. A spectrometer according to claim 14 The method of claim 11, characterized in that the horizontal distances between the measuring electrodes (18) in the upper and lower pairs constitute 50-90% of the thickness of the glass substrate (6). 15. A spectrometer according to claim 15 The method of claim 1, characterized in that the separator channel (20), constituting the drift region, is an elongated recess, and symmetrically with respect to the axis of the separator channel 20, a set of introducing electrodes (17) consisting of at least two pairs of electrodes is attached to the upper surface of the glass substrate (6). followed by the first pair of forming electrodes (21), and at the end of the separator chamber (3) a second pair of forming electrodes (21) and a single detector electrode (4), the working surfaces of the introducing electrodes (17) and detector electrodes (4) overlap the surface of the channel (20). 16. A spectrometer according to claim 16 The method of claim 15, characterized in that the introducing electrodes (17) and the forming electrodes (21) are made in the form of 0.5 mm wide silicon microcantilever. 17. A spectrometer according to claim 15. The method of claim 15, characterized in that the separator channel (20) being the particle drift region has a length of 20 mm to 35 mm. 18. A spectrometer according to claim 18 3. The method of claim 1, characterized in that the separator channel (20) in the glass substrate (6) in the separator chamber (2), constituting the particle drift area, is an elongated recess, and symmetrically with respect to the channel axis (21) connected to the upper surface of the glass substrate (6) there is a set of introducing electrodes (17) consisting of at least two pairs of introducing electrodes, then a pair of compensating electrodes (22), made in the form of parallel, elongated rectangles, and at the end of the chamber, a pair of aperture electrodes (23) in the form of microcantilever and a single detector electrode (4), the surfaces of the introducing electrodes (17), the compensating electrodes (22) and the aperture electrodes (23) and the detector electrodes (4) overlap the surface of the separator channel (20), and there is a voltage between the compensating electrodes (22) 20 V to 300 V, preventing ions twisting as a result of the magnetic field. 19. Spectrometer according to claim 1 18. The method according to claim 18, characterized in that a magnetic field of 0.1 to 0.8 T prevails in the separator chamber (3) perpendicular to its surface.