RU2496919C1 - Method of pre-treatment of carbon-bearing carrier of electrochemical catalyser - Google Patents

Abstract

FIELD: metallurgy.

SUBSTANCE: treatment of carbon-bearing carrier of an electrochemical catalyser is performed in a vacuum chamber equipped with a source of flow of atomic particles and a holder of carbon powder, which has the possibility of mixing the powder; powder of carbon-bearing carrier is mixed, and surface of the carrier is bombarded with a beam of atomic particles; besides, in order to arrange powder of carbon-bearing carrier, there used is a porous substrate installed in the holder and having open porosity, and made from inert material, and pneumatically connected to an autonomous gas supply device; layers of particles of carbon-bearing carrier are put on the substrate; inert gas is blown through the porous substrate so that a fluidised layer of carbon-bearing carrier particles is formed above the substrate, and bombardment of surface of particles of carbon-bearing carrier is performed with ion energy of not less than 7.41 eV/atom.

EFFECT: improving activation efficiency of surface of fine and nanosized carrier of electrochemical catalysers.

Description

The invention relates to the field of electrochemistry, and in particular, to methods for pretreating carbon carriers of electrochemical catalysts used in electrolyzers and solid polymer electrolyte fuel cells, and can be used as a preparatory stage for the production of electrocatalysts.

It is known that anodic and cathodic electrochemical catalysts are an integral part of electrolyzers and fuel cells with solid polymer electrolyte (S. I. Kozlov, V. N. Fateev “Hydrogen Energy: Current State, Problems, Prospects” M., Gazprom VNIIGAZ, 2009, p. 28-35, 337-339). In this case, the specific productivity of the fuel cell or electrolyzer is proportional to the surface area of the catalyst. To create electrocatalysts with a high specific surface and low metal content, carriers with a well-developed surface are used. Various carbon materials with high dispersion, electrical conductivity, thermal and corrosion resistance, such as various types of soot, mesocarbon beads, fullerenes, carbon nanotubes, nanofibers, etc., have become widely used as supports for electrocatalysts (N.V. Kuleshov, VN Fateev, MA Osina "Nanotechnology and nanomaterials in electrochemical systems" M, MPEI, 2010, pp. 9-11).

The influence of the size and morphology of the surface of the carbon carrier on the dispersion and catalytic activity of the deposited catalyst is known. So, the number and distribution of catalyst particles is affected by the presence and distribution of defects on the surface of the carbon carrier (N.V. Kuleshov, V.N. Fateev, M.A. Osina “Nanotechnologies and nanomaterials in electrochemical systems” M., MPEI, 2010 ., p.13-16). It is desirable to be able to obtain a uniform distribution of the catalyst particles over the entire surface of the carbon carrier while providing the required particle density, depending on the specific requirements of the catalyst.

Known methods for the chemical production of carbon-supported electrocatalysts, in which the surface of a carbon carrier having high specific surface area is pre-treated (see, for example, N.V. Kuleshov, V.N. Fateev, M.A. Osina, “Nanotechnologies and Nanomaterials in electrochemical systems ”M., MPEI, 2010, p.12). At the same time, functional groups that prevent the adsorption of the precursor, which subsequently participates in the chemical deposition of catalyst particles on the surface of the carbon carrier, are chemically removed from the surface of the carbon carrier, and surface functional groups that promote the formation of adsorption centers are chemically grafted. The number and distribution of such groups determines the quantity and distribution on the surface of the carbon carrier of the catalyst particles synthesized hereinafter by one of the known chemical methods.

The disadvantages of these chemical methods for pre-treatment of the carbon carrier are their complexity, low environmental friendliness, the high time required for their implementation, as well as their limited scope (it is possible to use only with further chemical synthesis of catalysts). In addition, these methods do not provide a uniform distribution of activation centers over the entire surface of the carbon carrier.

A known method of pre-processing a carbon carrier made in the form of multilayer carbon nanotubes (Chien-Chung Chen, Chia-Fu Chen, Chieng-Ming Chen, Fang-Tzu Chuang Electrochemistry Communications 9 (2007) 159-163). When implementing this method, the carbon carrier is placed in a 15 M solution of nitric acid, heated to 80 ° C, kept at a given temperature for 18 hours, then the carbon carrier is filtered off in deionized water using a 0.1 mm polytetrafluoroethylene membrane. The disadvantage of this method is its complexity, low environmental friendliness, high time required for its implementation, limited scope (it is possible to use only with further chemical synthesis of the catalyst). In addition, this method does not provide a large number and uniform distribution of activation centers over the entire surface of the carbon carrier.

A known physicochemical method for pre-processing a carbon carrier made in the form of multilayer carbon nanotubes (Chien-Chung Chen, Chia-Fu Chen, Chieng-Ming Chen, Fang-Tzu Chuang Electrochemistry Communications 9 (2007) 159-163). In this case, the carbon carrier is placed in a tube made of chemically inert glass, filled with a 5M solution of nitric acid, for 20 minutes. heated to 210 ° C in a microwave oven with a power of 100 W, kept at a predetermined temperature for 30 minutes, then the carbon carrier is filtered off in deionized water using a 0.1 mm polytetrafluoroethylene membrane. The application of this method allows to reduce the activation time of the surface of carbon nanotubes and to obtain a larger number of active centers required for further chemical synthesis of catalyst particles in comparison with the chemical method described above. The disadvantages of this method include the limited scope (it is possible to use only in the further chemical synthesis of the catalyst), low environmental friendliness, due to the need to use chemical reagents, time consuming (due to the need to filter the solution with particles of the carbon carrier), insufficient number of active centers on the surface of the carrier resulting from the application of this method, as well as the unevenness of their distribution on the surface of the carbon carrier.

A known method of physicochemical processing of flat and granular samples of carbon materials, adopted as a prototype, in which the surface of the carbon samples is treated with cold plasma (P. Favia, N. De Vietro, R. Di Mundo, F. Fracassi, R. d'Agostino, Tuning the acid / base surface character of carbonaceous materials by means of cold plasma treatments. Plasma Processes and Polymers 3 (2006) 66-74). The treatment is carried out at low pressure in the presence of an ammonia-oxygen mixture. In this case, the processed granular samples are placed in a horizontally placed glass beaker with inner blades, the samples are periodically mechanically mixed by rotating the beaker around its axis, the ammonia-oxygen gas mixture is injected into the beaker, where cold plasma is then excited and the surface of the carbon samples is treated in a stream of ionized particles cold plasma. The method allows you to chemically activate the surface of the processed samples by grafting oxygen and / or nitrogen-containing chemical groups. The disadvantages of the method include the low efficiency of its application for the activation of carbon carriers of electrochemical catalysts, such as carbon black, nanotubes or nanofibers, with a highly developed surface. Due to the adhesion and coarsening of particles during their mechanical mixing, the active surface of the carbon carrier is significantly reduced, while part of the surface of the carbon carrier remains inaccessible to the flow of the processing plasma. In addition, the disadvantages of this method include the limited scope of its application. In particular, it is applicable only in the case of further use of chemical methods for the deposition of catalyst particles. The presence of grafted oxygen or nitrogen-containing chemical groups does not provide for the precipitation of catalyst particles upon further use of physical methods of catalyst deposition.

The technical result to which the invention is directed is to increase the surface activation efficiency of finely dispersed and nanosized carbon carriers of electrochemical catalysts by increasing the uniformity and providing a high density of distribution of activation centers over the working surface of the carrier particles, as well as expanding the scope of the method by creating activation centers for carbon material suitable for further chemical or physical deposition of electrocatalyst particles.

To achieve the specified technical result, a method for pre-treating a carbon carrier of an electrochemical catalyst is proposed, the process being carried out in a vacuum chamber equipped with a source of atomic particle flow and a carbon powder holder configured to mix the powder, the carbon carrier powder is mixed and the carrier surface is bombarded a beam of atomic particles, while using a holder mounted to hold the carbon carrier powder porous substrate with open porosity made of an inert material pneumatically connected to an autonomous gas supply device, layers of carbon carrier particles are placed on the substrate, an inert gas is blown through the porous substrate to form a pseudo-boiling layer of carbon carrier particles over the substrate, and the surface of the carbon carrier particles is bombarded with an ion energy of at least 7.41 eV / atom.

A distinctive feature of the invention is that a porous substrate with open porosity installed in the holder made of an inert material pneumatically connected to an autonomous gas supply device is installed to hold the carbon carrier powder, layers of carbon carrier particles are placed on the substrate, an inert gas is blown through the porous substrate with the formation of a pseudo-boiling layer of carbon carrier particles over the substrate, and the surface of the carbon carrier particles is bombarded with energy atomic particles is not less than 7.41 eV / atom.

The use of the proposed method for pre-treating a carbon carrier of an electrochemical catalyst installed in the holder of a porous substrate with open porosity pneumatically connected to an autonomous gas supply device with a smooth increase in the inert gas flow passing through the pores of the substrate leads to the appearance of a pseudo-boiling layer in the volume of carbon particles located on the substrate carrier. At the same time, due to the small size and weight of the particles of the carbon carrier, as well as the separation of the ascending gas flows by the pores of the substrate, intensive mixing of the carbon particles occurs, giving them additional torque. As a result of this, almost the entire working surface of the particles of the carbon carrier becomes accessible for irradiation with a flow of feed atomic particles. The implementation of the porous substrate of an inert material prevents unwanted contamination of the carbon carrier during processing. During the bombardment of carbon carrier particles by a stream of atomic particles with an energy of at least 7.41 eV / atom, practically significant radiation defects arise in the surface carbon layer. (In this case, an atomic particle is understood not only as an isolated atom, but also derivatives from it: atomic (monatomic) ion, atomic radical, atomic radical ion, formed as a result of ionization or excitation of an atom and capable of independent existence) Threshold value of the energy of incident atomic particles (7.41 eV / atom) corresponds to the sublimation energy of carbon atoms. These defects in the structure of the carbon carrier are activation centers during subsequent chemical or physical synthesis of electrocatalyst particles. This ensures uniformity and a high density of distribution of activation centers over the entire working surface of the carbon particles of the electrocatalyst carrier. The specific values of the distribution density are determined by the parameters of irradiation with a beam of incident atomic particles. In the case of further use of chemical methods for the synthesis of electrocatalysts, the resulting radiation defects on the surface of the carbon carrier are the centers of deposition of oxygen and / or nitrogen-containing chemical groups, which in turn are centers of chemical synthesis of the catalyst.

Thus, in addition to using a porous substrate with open porosity installed in the holder, made of an inert material and pneumatically connected to an autonomous gas supply device, the carbon carrier particles are placed on the substrate, layers of carbon carrier particles are placed on the substrate, and an inert gas is blown through the porous substrate with the formation of a pseudo-boiling layer of carbon carrier particles over the substrate, and the surface of the particles of the carbon carrier powder is bombarded with atomic energy at least 7.41 eV / atom provides an increase in the surface activation efficiency of finely dispersed and nanosized carbon carriers of electrochemical catalysts by increasing uniformity and providing a high density of distribution of activation centers over the working surface of carrier particles, as well as expanding the scope of the method by creating activation centers for carbon material, suitable for further chemical or physical deposition of electrocatalyst particles.

The method is as follows. The carbon carrier of the electrochemical catalyst is pretreated in a vacuum chamber with an adjustable ion source installed in it and a carbon powder holder with a substrate made of porous inert material with open porosity (for example, porous titanium obtained by powder metallurgy). In this case, the porous substrate is pneumatically connected to a device for autonomous gas supply. (A device for autonomous gas supply to a porous substrate can be located both outside and inside the vacuum chamber. The simplest version of such a device can be a gas cylinder with a controlled gas outlet located outside the vacuum chamber and pneumatically connected to the porous substrate inside the vacuum chamber with the possibility of transmission gas through the porous substrate.) On the porous substrate, the processed carbon carrier powder is layered in layers. The vacuum chamber is pumped to vacuum values determined by the operational characteristics of the atomic particle stream source. (Such a source of atomic particles can be, for example, a source of accelerated ions or a source based on magnetron, plasma or laser sputtering of target material.) An inert gas is passed through a porous substrate, gradually increasing the gas supply, until a stable pseudo-boiling layer of carbon particles forms carrier. The moment of occurrence of the pseudo-boiling layer can be observed visually through the inspection window of the vacuum chamber. Then the pseudo-boiling particles of the carbon carrier are irradiated with a stream of atomic particles with an energy of at least 7.41 eV / atom. In case of exceeding the permissible pressure of the residual gases in the vacuum chamber, the necessary additional pumping of gas is carried out (using standard means providing vacuum of the working chamber).

The proposed method for pre-processing a carbon carrier was tested during pre-processing of carbon black brand Vulcan XC-72, widely used as a carbon carrier of a platinum catalyst. In this case, a plate of porous titanium with a diameter of 70 mm, a thickness of 0.9 mm, with a porosity of 28% and an average pore size of ~ 10 μm made of powdered titanium was used as a porous substrate. Additionally, in order to prevent soot scattering, the porous titanium substrate was equipped with a protective rim. The thickness of the carbon support layer on the porous substrate was ~ 2 mm. Argon was used to form a pseudo-boiling layer of a carbon carrier by purging an inert gas through a porous substrate. In this case, after evacuation of the working chamber, the flow of argon through the porous substrate was gradually increased. The moment of formation of a pseudo-boiling layer of carbon carrier particles was observed visually through the sight glass of the vacuum chamber. The pressure in the working chamber after the formation of a stable pseudo-boiling of carbon carrier particles did not exceed 0.270 mbar. In the general case, the pumping pressure and the inert gas flow through the porous substrate necessary for the formation of stable pseudo-boiling of the carbon carrier depend both on the parameters of the particular porous substrate used to implement the proposed method and on the properties of the carbon carrier being treated, as well as on the thickness of the carrier layer. In order to further automate the pre-treatment of the carbon carrier, it is possible to experimentally determine the pressure and inert gas flow rate to create a stable pseudo-boiling layer of carbon powder and maintain the necessary parameters during the processing. The pseudo-boiling layer of the carbon support was treated with a stream of argon ions with an energy of ~ 20 eV / ion. The processing time was 10 minutes. Depending on the specific requirements for the density of distribution of the activation centers on the surface of the particles of the carbon carrier, as well as on the capabilities of the particular source of atomic particle flux used during the treatment (in particular, on the flux density of atomic particles), the required the distribution density of activation centers by changing the processing time and / or the density of the irradiating stream. The presence and distribution of the obtained activation centers on the surface of the particles of the carbon support of the electrochemical catalyst was verified by electron microscopy after additional chemical deposition of platinum particles. After conducting studies of five different samples of the carbon support, no particles were detected whose individual parts of the surface would have an abnormally low content of activation centers (i.e., there were no zones with a visually different density of distribution of activation centers). All studied samples of samples of particles of a carbon carrier were characterized by a high density of distribution of activation centers. In the general case, the distribution density of activation centers depends on the flux density of the irradiating particles, the irradiation time, and also the parameters of the fluidized bed of carbon carrier particles.

Thus, the proposed method for pretreatment of a carbon carrier of particles of an electrochemical catalyst provides an increase in the surface activation efficiency of finely dispersed and nanoscale carbon carriers of electrochemical catalysts by increasing uniformity and providing a high density of distribution of activation centers over the working surface of the carrier particles. In addition, the scope of the method has been expanded by creating activation centers for carbon material suitable for further chemical as well as physical deposition of electrocatalyst particles.

Claims (1)

A method of pretreating a carbon carrier of an electrochemical catalyst, the method being that the processing is carried out in a vacuum chamber equipped with a source of atomic particle stream and a carbon powder holder configured to mix the powder, the carbon carrier powder is mixed, the surface of the carrier is bombarded with a beam of incident atomic particles, characterized in that a porous substrate with an open by means of a substance made of an inert material, pneumatically connected to an autonomous gas supply device, layers of carbon carrier particles are placed on the substrate, an inert gas is blown through the porous substrate to form a pseudo-boiling layer of carbon carrier particles over the substrate, and atomic particle energy is bombarded on the surface of the carbon carrier particles not less than 7.41 eV / atom.