JP6102624B2 - Method for manufacturing disk electrode for electrochemical measurement - Google Patents

Description

  The present invention relates to a method of manufacturing a disk electrode for electrochemical measurement. More specifically, the present invention relates to a method for producing a disk electrode for electrochemical measurement using a catalyst ink containing catalyst particles, a hydrogen ion conductive polymer electrolyte, and ultrapure water and not containing a monohydric alcohol.

  The so-called Polymer Electrolyte Fuel Cell (hereinafter referred to as “PEFC”) has many advantages such as low operating temperature, light weight and reduced power generation loss. For this reason, PEFC can be applied to fuel cell vehicles, household cogeneration systems, etc. In order to widely disseminate PEFC, PEFC must have high power generation capacity. It is important, and it is necessary to precisely evaluate the catalytic activity of the electrode catalyst (catalyst used by forming a thin layer on the electrode) that causes the power generation capability.

  The catalytic activity can be evaluated based on the result of cyclic voltammetry (hereinafter, “CV”) measurement obtained by a test method such as a fixed electrode method, a rotating electrode method, or a channel flow electrode method. The catalytic activity evaluation is performed by obtaining a cyclic voltammogram obtained from the result of CV measurement and measuring the oxidation-reduction starting potential from the waveform of this cyclic voltammogram.

  The rotating electrode method is generally employed for analysis of electrochemical reactions because it can control the supply rate of reactants to the electrodes. In the rotating electrode method, a reaction material is supplied to the electrode by rotating the electrode in an electrolyte solution in which the reaction material is dissolved, and the chemical reaction rate is adjusted based on the current value generated by the chemical reaction occurring on the electrode surface. taking measurement. When the measurement is performed by forming a catalyst layer on the surface of the rotating electrode, the rate of chemical reaction involving the catalyst, that is, the catalytic activity can be evaluated (for example, Non-Patent Document 1).

  A rotating disk electrode method (hereinafter, “RDE method”), which is one of the rotating electrode methods, employs a rotating disk electrode in which the shape of a catalyst electrode is a disk shape. The RDE method generates a thin diffusion layer in the electrolyte solution by rotating the rotating disk electrode. The RDE method can obtain a good current-potential curve by regulating the movement of the reactant in the electrolyte solution by the rotation speed of the rotating disk electrode due to the presence of the thin diffusion layer.

  For example, using a rotating disk electrode made of glassy carbon (GC), a rotating disk electrode having a catalyst layer formed on the surface of the rotating disk electrode is manufactured. By rotating the rotating disk electrode, the reactant contained in the electrolyte solution is supplied to the catalyst layer formed on the surface of the rotating disk electrode. The reaction rate due to the electrode reaction of the reactant generated in the catalyst layer is measured as a current value. The catalytic activity can be evaluated by calculating the rate of the catalytic reaction from the current value.

  In addition, a rotating ring disk electrode method (hereinafter referred to as “RRDE method”), which is one of the rotating electrode methods, includes a rotating disk electrode having a disk shape and a concentric ring electrode around the rotating disk electrode. The provided rotating ring disk electrode is adopted. In the RRDE method, a reactant or product generated at a disk electrode can be detected by oxidation or reduction at a ring electrode.

  In both the RDE method and the RRDE method, in order to evaluate the catalyst activity with higher accuracy, the catalyst layer formed on the surface of the disk electrode covers the entire surface of the disk electrode, and the thickness thereof is uniform. And it must be smooth.

  When a disk electrode in which the entire surface of the disk electrode is not covered with the catalyst layer is used, that is, there is a portion where the catalyst layer is not distributed on the surface of the disk electrode. Since the catalyst functions to accelerate the electrode reaction by the reactants in the electrolyte solution, the electrode reaction does not occur or the target electrode reaction occurs in the part where the catalyst layer is not distributed on the surface of the disk electrode. A different reaction may occur. For this reason, when a disk electrode in which the entire surface of the disk electrode is not covered with the catalyst layer is used, there is a disadvantage that the catalytic activity inherent in the electrode cannot be accurately evaluated.

  If the catalyst layer formed on the surface of the disk electrode is not smooth, the distance until the reactant in the electrolyte solution reaches the surface of the catalyst layer is not constant, that is, supplied to the catalyst layer per unit time. The amount of reactive material is not constant. For this reason, there is a problem that the current value depending on the supply of the reactant varies, and the electrode reaction rate calculated therefrom also varies.

Further, when the thickness of the catalyst layer formed on the surface of the disk electrode is not uniform, a portion where the catalyst layer is thick causes a measurement error due to a decrease in measurement current due to the electric resistance of the catalyst layer itself. Also,
The catalyst particles present at the bottom of the catalyst layer do not come into contact with the reactant and do not participate in the electrode reaction at all. That is, only the surface layer of the catalyst layer formed on the disk electrode is involved in the electrode reaction, causing a problem that the activity per unit catalyst amount is apparently calculated low.

As a method of forming the catalyst layer on the surface of the disk electrode, the method shown in Non-Patent Document 1 (III-2-4 Electrode Preparation Method) is usually used. Here, after dispersing the catalyst powder in an aqueous solution of monohydric alcohol, the catalyst ink prepared by adding a solid electrolyte dispersion as a binder is dropped on the disk electrode and dried in a thermostatic chamber (60 ° C.) for about 15 minutes. Thus, a catalyst layer is formed on the surface of the disk electrode.
In addition, a method for manufacturing an electrode for electrochemical measurement in which a catalyst layer is formed without using a binder by a gas phase process has been proposed (for example, Patent Document 1). Furthermore, it has been proposed that a composition containing an electrode catalyst, a conductive material, and an anion exchange resin is formed in a layered manner on the surface of a disk electrode and used as a catalyst layer (for example, Patent Document 2). The applicant of the present patent presents the following publications as publications describing the above known invention.

“Proposals for Targets, R & D Issues and Evaluation Methods for Polymer Electrolyte Fuel Cells” published in January 2011 by the Council for Promotion of Practical Fuel Cell (FCCJ)

JP 2005-292097 A JP 2011-216247 A

  However, in the method disclosed in Non-Patent Document 1, heat is generated when the monohydric alcohol contained in the catalyst ink adjustment process and the active metal in the catalyst particles come into contact with each other, thereby promoting the aggregation of the catalyst particles. Further, droplet aggregation occurs in the process of drying the catalyst ink within a relatively short time in a temperature rising environment. As a result, the particle size of the catalyst particles, the thickness of the catalyst layer, and the distribution of the catalyst particles become non-uniform, and the smoothness of the surface of the catalyst layer is impaired or a portion not covered with the catalyst layer is generated. On the other hand, in the method for producing an electrode for electrochemical measurement described in Patent Document 1, although a catalyst layer not containing a binder can be formed by a vapor deposition process to remove film resistance and overvoltage of the catalyst layer, the catalyst layer The purpose is to measure the activity of the catalyst accurately and reproducibly because of the change in the reaction area due to the separation of the catalyst layer during measurement, which is difficult to ensure a sufficiently high adhesion between the electrode and the electrode substrate. Cannot be reached. In addition, the electrolyte material described in Patent Document 2 has no effect of suppressing aggregation of catalyst particles because of the addition of monohydric alcohol during the catalyst ink preparation process, and further uses an anion exchange resin electrolyte as a binder. The original purpose of measuring catalytic activity as an indicator of practical performance is to measure electrode reactions based on a principle different from PEFC using hydrogen ion conductive (ie, cation exchange resin) electrolytes widely used in I can not reach.

  The present invention has been made in view of such technical circumstances, and provides a method for manufacturing a disk electrode for electrochemical measurement in which the entire surface of the disk electrode is coated and a uniform and smooth catalyst layer is formed. Is an issue. Another object of the present invention is to provide an electrochemical measurement disk electrode obtained by the electrochemical measurement disk electrode manufacturing method and an electrochemical measurement device provided with the electrochemical measurement disk electrode. .

  As a result of diligent study, the inventors of the present invention, as catalyst ink used for forming a catalyst layer on the surface of the electrochemical measurement disk electrode, include catalyst particles, a hydrogen ion conductive polymer electrolyte, and ultrapure water. The present inventors have found that a disc electrode that can evaluate the catalytic activity with extremely high accuracy can be manufactured by employing a catalyst ink containing no hydrogen and no monohydric alcohol. More specifically, the present invention includes the following technical matters.

(1) A method of manufacturing a disk electrode for electrochemical measurement,
(i) a step of preparing a catalyst ink containing catalyst particles in which an active metal is supported on a carrier, a hydrogen ion conductive polymer electrolyte, and ultrapure water, and containing no monohydric alcohol;
(ii) dropping the catalyst ink on the surface of the disk electrode to form a coating layer made of the catalyst ink;
(iii) drying the coating layer made of the catalyst ink at 10 to 30 ° C .;
A method of manufacturing a disk electrode for electrochemical measurement, comprising:

(2) The specific resistance R of the ultrapure water is represented by the following general formula:
The method for producing a disk electrode for electrochemical measurement according to claim 1, wherein the specific resistance is 3.0 MΩ · cm or more.
In the above general formula, R represents specific resistance, and ρ represents electrical conductivity measured by a JIS standard test method (JIS K0552).

(3) The step (i) of preparing the catalyst ink includes:
(ia) Mixing the catalyst particles and the ultrapure water to prepare a catalyst particle slurry,
(ib) A hydrogen ion conductive polymer electrolyte aqueous solution in which the hydrogen ion conductive polymer electrolyte and ultrapure water are mixed is prepared in advance,
(ic) The method for producing a disk electrode for electrochemical measurement according to (1) or (2), wherein the hydrogen ion conductive polymer electrolyte aqueous solution is added to the catalyst particle slurry.

(4) To the catalyst particle slurry obtained in the step (ia),
The hydrogen ion conductive polymer electrolyte aqueous solution obtained in the step (ib) is added at an addition rate of 1.0 to 10.0 ml / min,
The method for producing a disk electrode for electrochemical measurement according to (3), wherein a catalyst ink in which the catalyst particles are uniformly dispersed is prepared.

  (5) The electricity according to any one of (1) to (4), wherein the catalyst particles are contained in an amount of 0.05 to 1.0 part by weight with respect to 100 parts by weight of the catalyst ink. Manufacturing method of chemical measurement disk electrode.

  (6) The step of drying the coating layer made of the catalyst ink is performed at a temperature of 10 to 30 ° C. and a humidity of 20 to 80% RH. 2. A method for producing a disk electrode for electrochemical measurement according to 1.

  (7) The method (1) to (6) for producing a disk electrode for electrochemical measurement according to any one of (1) to (6), wherein the step (iii) of drying the coating layer made of the catalyst ink is performed for 2 to 6 hours. .

  (8) The method for producing a disk electrode for electrochemical measurement according to any one of (1) to (7), wherein the disk electrode for electrochemical measurement is a rotating disk electrode.

  (9) A disk electrode for electrochemical measurement obtained by the production method described in any one of (1) to (8).

  According to the present invention, the catalyst layer formed on the surface of the disk electrode covers the entire surface of the disk electrode, the thickness of the catalyst layer is uniform and smooth, and the catalyst particle component in the catalyst layer is uniform. A method of making a distributed electrochemical measurement disk electrode is provided. In addition, according to the present invention, there is provided a method for producing a disk electrode for electrochemical measurement that can accurately measure the catalytic activity inherent in a catalyst such as PEFC.

It is the flowchart which showed each process of the manufacturing method of the disk electrode for electrochemical measurements. FIG. 3 is an image diagram showing a state of catalyst particles at an interface of a rotating disk electrode. It is the schematic of the rotating disk electrode measuring apparatus provided with the rotating disk electrode. It is the figure which graphed the mass activity relative value (%) of the rotating disk electrode of Example 1 with respect to Comparative Example 1. It is the figure which graphed the mass activity relative value (%) of the rotating disk electrode of Example 3 with respect to Comparative Example 2.

<Manufacturing method of disk electrode for electrochemical measurement>
The method for producing a disk electrode for electrochemical measurement of the present invention comprises a step of preparing a catalyst ink, a step of forming a coating layer made of the catalyst ink, and a step of drying the coating layer made of the catalyst ink. Yes. FIG. 1 is a flowchart showing each step of a method for producing an electrochemical measurement disk electrode. Hereinafter, each step will be described in detail.

(Process for preparing catalyst ink (i))
The step of preparing the catalyst ink includes mixing catalyst particles, which are catalyst components of the catalyst ink, a hydrogen ion conductive polymer electrolyte, and ultrapure water, and dispersing them to uniformly distribute these components. This is a step of preparing ink.

[Catalyst particles]
The catalyst particles are formed by having an active metal and a carrier as its components and carrying the active metal on the carrier. As the catalyst species, that is, the active metal and the carrier, those suitable for the intended electrode reaction can be appropriately selected and are not particularly limited. For example, when measuring the electrode reaction of PEFC, the active metal is a metal that can sufficiently perform the oxidation reaction of hydrogen gas at the negative electrode of the polymer electrolyte fuel cell and the reduction reaction of oxygen gas at the positive electrode. Can be used.

  In general, the active metal having catalytic ability includes, for example, metals such as platinum, ruthenium, iridium, rhodium, palladium, tungsten, lead, iron, chromium, cobalt, nickel, manganese, vanadium, molybdenum, gallium, and aluminum, or An alloy composed of a combination of any of these metals can be exemplified.

  The active metal loading rate may be a loading rate suitable for promoting the excitation of the target electrode reaction, and may be, for example, 5 to 80% by weight with respect to the total weight of the catalyst particles.

  Examples of the carrier constituting the catalyst particles include, for example, glassy carbon (GC), fine carbon, carbon black, graphite, carbon fiber, activated carbon, carbon nanofiber, and carbon nanotube from the viewpoint of adsorption with an active metal and the surface area of the carrier. It can be suitably selected from carbon-based materials such as glass-based materials or oxide-based glass-based materials or ceramic-based materials.

  The catalyst particles are produced by supporting an active metal on a support by a known method such as an impregnation method, a liquid phase reduction method, or an electrochemical deposition reaction.

  The catalyst ink contains ultrapure water. In general, ultrapure water means pure water having a very high purity and containing no organic impurities. In the present invention, the ultrapure water contained in the catalyst ink has a specific resistance R (reciprocal of electrical conductivity measured by JIS standard test method (JIS K0552)) represented by the following general formula: 3.0 MΩ · It is preferable that it is cm or more.

In the above general formula, R represents specific resistance, and ρ represents electrical conductivity measured by a JIS standard test method (JIS K0552).

  When pure water with a specific resistance R of less than 3.0 MΩ · cm is used, the current value due to the impurities contained in the pure water being involved in the electrode reaction is also measured. It cannot be measured accurately.

  A higher specific resistance R is preferable because there are fewer impurities, but ultrapure water having a specific resistance value in a practically manufacturable range can be used as long as it is 3.0 MΩ · cm or more and 20.0 MΩ · cm or less. Ultrapure water suitable for the preparation of such a catalyst ink can be produced by, for example, an ultrapure water production apparatus “Milli-Q series” sold by Merck Millipore Business Division, but is not limited thereto.

  Usually, a catalyst ink for a fuel cell often contains a monohydric alcohol such as ethyl alcohol as a component in order to improve wettability with a carrier and compatibility with a hydrogen ion conductive polymer electrolyte. However, in the case of containing a monohydric alcohol, in the process of mixing and dispersing with catalyst particles and ultrapure water in the process of preparing the catalyst ink, or in the process of applying the catalyst ink in the process of forming the disk electrode, In the drying process, heat is generated when the monohydric alcohol and the active metal come into contact with each other, and the aggregation of the catalyst particles is promoted. The catalyst particles aggregate and become coarse, and only the catalyst particles located on the surface of the aggregate are subject to electrochemical measurement, and as a result, the original catalytic activity of the active metal present in the disk electrode can be accurately evaluated. I can't.

[Hydrogen ion conducting polymer electrolyte]
The catalyst ink contains a hydrogen ion conductive polymer electrolyte as a binder component in order to disperse the catalyst particles and improve the adhesion between the catalyst layer of the disk electrode and the disk electrode substrate. The binder contained in the catalyst ink only needs to have the function of fixing the catalyst particles. However, in order to avoid the occurrence of an electrode reaction different from the original purpose without inhibiting the original electrode reaction, It is desirable to have ionic conductivity. Further, in order to accurately evaluate the catalyst activity, it is necessary that the catalyst particles do not peel off from the electrode substrate during the measurement, and therefore it is desirable that the binder be dispersed as uniformly as possible between the catalyst particles. .

  The hydrogen ion conductive polymer electrolyte is not particularly limited, and examples thereof include known perfluorocarbon resins having a sulfonic acid group and a carboxylic acid group. Nafion (trademark) can be illustrated as a hydrogen ion conductive polymer electrolyte which can be obtained easily.

  Specific examples of the hydrogen ion conductive polymer electrolyte include 10% Nafion (registered trademark) dispersion solution DE1021CS type (manufactured by Wako Chemical Co., Ltd.), 10% Nafion (registered trademark) dispersion solution DE1020 type (Wako Co., Ltd.). Chemical).

  The catalyst ink can be prepared by mixing, pulverizing, and stirring the catalyst particles described above, ultrapure water, and a hydrogen ion conducting polymer electrolyte. The catalyst ink can be prepared using a pulverizing mixer such as an ultrasonic disperser or a ball mill disperser. The pulverization conditions and the stirring conditions when operating the ultrasonic disperser can be appropriately set according to the mode of the catalyst ink.

  The composition of each component of the catalyst particles, ultrapure water, and hydrogen ion conductive polymer electrolyte contained in the catalyst ink has a good dispersion state of the catalyst particles, and the catalyst layer of the disk electrode covers the entire surface of the disk electrode. It is necessary to set appropriately so as to form a uniform and smooth catalyst layer.

  The composition of each component is preferably 0.03 to 0.30 parts by weight of hydrogen ion conductive polymer electrolyte and 300 to 1000 parts by weight of ultrapure water with respect to 1 part by weight of catalyst particles. More preferably, the hydrogen ion conductive polymer electrolyte is 0.05 to 0.10 parts by weight and the ultrapure water is 500 to 800 parts by weight with respect to 1 part by weight of the catalyst particles.

  When the composition of each component is within the above range, the coating film made of the catalyst ink forming the catalyst ink layer of the disk electrode is preferably not excessively spread on the disk electrode at the time of film formation. It is preferable because a coating film having a smooth and uniform thickness can be formed. The weight of the hydrogen ion conductive polymer electrolyte is the weight in a dry state, and the weight of ultra pure water is the weight including the ultra pure water contained in the hydrogen ion conductive polymer electrolyte solution.

  In addition, the step (i) of preparing the catalyst ink only needs to be able to prepare a catalyst ink that covers the entire surface of the disk electrode and has a good dispersion state of the catalyst particles and forms a uniform and smooth catalyst layer. The preparation process is not particularly limited.

  For example, the step (i) of preparing the catalyst ink, the step (ia) further mixing the catalyst particles and the ultrapure water to prepare a catalyst particle slurry, and the step (ib) the hydrogen ion conductive polymer electrolyte. And preparing a hydrogen ion conductive polymer electrolyte aqueous solution in which ultrapure water is mixed in advance, and step (ic) adding the hydrogen ion conductive polymer electrolyte aqueous solution to the catalyst particle slurry and preparing each step. It may be.

  That is, in the step (ia), a catalyst slurry comprising catalyst particles and ultrapure water is prepared. Separately from the catalyst slurry prepared in step (ia), in step (ib), a hydrogen ion conductive polymer electrolyte aqueous solution comprising a hydrogen ion conductive polymer electrolyte and ultrapure water is prepared in advance. Then, in step (ic), a catalyst ink is prepared by adding the aqueous hydrogen ion conductive polymer electrolyte solution prepared in step (ib) to the catalyst slurry prepared in step (ia). Thus, by dividing the step (i) of preparing the catalyst ink into the steps consisting of steps (ia) to (ic), the dispersed state of the catalyst particles in the catalyst ink becomes good, and the catalyst ink layer of the disk electrode A catalyst ink suitable for the above can be prepared.

  Furthermore, it is also effective to add the hydrogen ion conductive polymer electrolyte aqueous solution obtained in the step (ib) to the catalyst particle slurry obtained in the step (ia) at a constant addition rate. By adding the hydrogen ion conductive polymer electrolyte aqueous solution to the catalyst particle slurry at a constant addition rate, the dispersion state of the hydrogen ion conductive polymer electrolyte with the catalyst particles in the catalyst ink is maintained well, and the catalyst This is because an ink can be prepared. Specifically, it is preferable to prepare a catalyst ink by adding at an addition rate of 1.0 to 10.0 ml / min. An addition rate in the above range is preferable because a coating film made of catalyst ink is uniformly formed on the disk electrode while maintaining the dispersed state of the catalyst particles in the catalyst ink.

(Step of forming a coating layer made of catalyst ink (ii))
The step of forming the coating layer made of the catalyst ink is a step in which an appropriate amount of the catalyst ink prepared in the step (i) is taken and dropped onto the surface of the disk electrode to form the coating layer made of the catalyst ink. is there.

  The method of dripping the catalyst ink on the surface of the disk electrode is not particularly limited as long as a certain amount of the catalyst ink prepared in step (i) can be dripped onto the disk electrode at a constant dropping speed. Absent. A dropping device capable of dropping by a manual pipette, an electric pipette, electronic control, or the like may be used. Further, depending on the dropping amount of the catalyst ink, the kind and capacity of the dropping device such as a pipette can be appropriately selected. A predetermined catalyst ink is dropped on the disk electrode, and the plate is left in a state where a coating layer made of the catalyst ink is formed.

  Note that the step of forming the coating layer made of the catalyst ink is preferably performed while keeping the dispersed state of the catalyst particles in the catalyst ink as good as possible. For this purpose, for example, in the operation of dispensing the catalyst ink to a dropping device such as a pipette, the pipette is installed in a state where the catalyst ink container is installed in the ultrasonic vibration device and the catalyst ink is dispersed by ultrasonic irradiation. It is preferable to collect the catalyst ink in an equal dropping device.

(Step of drying catalyst ink layer (iii))
The step (iii) of drying the catalyst ink layer is a step of drying the coating layer made of the catalyst ink to form a catalyst ink layer on the disk electrode.

  In the step (iii) of drying the catalyst ink layer, the catalyst ink employs a catalyst ink containing catalyst particles, ultrapure water, and a hydrogen ion conductive polymer electrolyte. Even when the coating film is dried, aggregation of the catalyst particles due to contact between the monohydric alcohol and the catalyst particles does not occur. For this reason, the whole surface on a disk electrode is coat | covered and the coating layer which consists of a uniform and smooth catalyst ink can be formed.

  The step (iii) of drying the catalyst ink layer is performed by setting the drying temperature, drying time, and humidity, which are the drying conditions of the coating film made of the catalyst ink. In the step (iii) of drying the catalyst ink layer, the drying temperature is 10 to 30 ° C. That is, in the step (iii) of drying the catalyst ink layer, the coating film made of the catalyst ink can be dried in the range of room temperature. For example, if the room is air-conditioned, the drying temperature is 20 to 25 ° C. When the drying temperature is lower than 10 ° C., it is not practically preferable because the rate at which water serving as the solvent of the catalyst ink is evaporated from the coating film is low. On the other hand, when the temperature is 30 ° C. or higher, the rate at which the moisture in the catalyst ink volatilizes from the coating film is high, and thus the tendency of the catalyst particles to aggregate as the moisture evaporates becomes strong. And catalyst particles agglomerate. Such a drying temperature is much lower than 60 ° C., which is the drying temperature of the coating layer composed of the catalyst ink layer in the conventional method of manufacturing a disk electrode.

  In the step (iii) of drying the catalyst ink layer, the humidity is 20 to 80% RH. Humidity affects the drying rate of the coating film made of catalyst ink. If the humidity is within the above range, the entire surface on the disk electrode can be covered, and a coating layer made of a uniform and smooth catalyst ink can be formed.

  The drying time in the step (iii) of drying the catalyst ink layer needs to be appropriately set in consideration of the relationship between the drying temperature and the humidity. When the drying temperature is set to 10 to 30 ° C. and the humidity is set to 20 to 80% RH, the drying time is preferably 2.0 to 6.0 hours, and more preferably, the production time is improved. From the viewpoint, it is preferably performed for 2.5 to 3.5 hours. A drying time of 2.0 hours or longer is preferable because the ultrapure water contained in the catalyst ink layer evaporates and covers the entire surface of the disk electrode, thereby forming a uniform and smooth catalyst layer. If the drying time exceeds 6.0 hours, the fixing state between the catalyst layer and the disk electrode substrate may be deteriorated, and the working efficiency is lowered, which is not preferable.

<Disc electrode for electrochemical measurement>
The disk electrode includes a catalyst ink layer on a disk electrode base material and a bottom surface that is an interface where a catalytic reaction occurs. As the disk electrode base material, a chemically stable material such as platinum, gold, tungsten, etc. in addition to glassy carbon (GC) can be formed into a predetermined shape to form a disk electrode base material. The catalyst ink layer is formed on the disk electrode substrate by appropriately adopting catalyst particles to be measured.

  The disk electrode has a catalyst ink layer on the bottom surface that is fixed to the disk electrode substrate and the measuring device cell and contacts the electrolyte.

  FIG. 2 is a diagram schematically showing the state of the catalyst particles on the surface of the rotating disk electrode obtained by the method for manufacturing the disk electrode for electrochemical measurements of the present invention.

  FIG. 2A is a schematic diagram showing the state of the catalyst particles 44 at the interface of the disk electrode base material 42 when the catalyst ink according to the prior art is used. In FIG. 2A, since the catalyst ink contains a monohydric alcohol, the catalyst particles 44 aggregate, and the aggregated state, coarse particles, and the distribution state of the catalyst particles 44 on the electrode surface due to rapid drying are also shown. It seems to be uneven. For this reason, the surface of the catalyst layer included in the disk electrode base material 42 has irregularities and is not smooth, and the thickness of the catalyst layer X seems not to be constant.

  FIG. 2B is a schematic diagram showing the state of the catalyst particles 44 at the interface of the disk electrode base material 42 obtained by the method of manufacturing the disk electrode for electrochemical measurement of the present invention. By preparing from a catalyst ink that does not contain a monohydric alcohol, there is no aggregation of the catalyst particles 44, and by adopting appropriate drying conditions, the surface of the catalyst layer X provided in the disk electrode substrate is smooth with few irregularities. It seems that it is uniformly distributed on the electrode surface.

<Measurement of catalytic activity by disc electrode for electrochemical measurement>
According to the rotating disk electrode method (RDE method), the oxygen reduction current (ORR current) measurement value (i) and the limiting diffusion current measurement value (iL) of the electrochemical measurement disk electrode are measured. Based on the measurement results of the oxygen reduction current (ORR current) measurement value (i) and the limiting diffusion current measurement value (iL), the activity of the catalyst present on the electrode was evaluated.

(RDE method measuring device)
FIG. 3 shows a schematic diagram of the RDE method measuring apparatus D. As shown in FIG. 4, the RDE method measuring device D includes a measuring device cell 10, a reference electrode (RE) 20, a counter electrode (CE) 30, and a rotating disk electrode 40 serving as a working electrode. The counter electrode (CE) 30 is positioned to face the catalyst ink layer X formed on the bottom surface of the rotating disk electrode 40.

  The reference electrode (RE) 20, the counter electrode (CE) 30, the rotating disk electrode 40, and the electrolytic solution 60 that constitute the RDE method measurement apparatus D are not particularly limited, but for example, as the reference electrode (RE) 20 Platinum (Pt) can be employed as the silver / silver chloride electrode (Ag / AgCl) and the counter electrode (CE) 30. A carbon material such as glassy carbon (GC) can be used as the disk electrode base material 42 of the rotating disk electrode 40. As the electrolytic solution 60, a known electrolytic solution that can be used in the RDE method can be employed.

  The rotating disk electrode 40 is fixed to the upper part of the measuring device cell 10 by a fixed base 50. Further, the gap between the measuring device cell 10 and the support portion 52 that supports the fixed base 50 and the rotating disk electrode 40 is sealed with an oil seal 54.

  The rotating disk electrode 40 is connected to a driving device (not shown), and is rotated in a horizontal direction facing the bottom surface of the measuring device cell 10 by the driving device (not shown). The measuring device cell 10 and the reference electrode (RE) cell 22 are filled with the electrolytic solution 60. Further, a gas inlet 12 is provided in the lower part of the side surface of the measuring device cell 10, and argon gas or oxygen gas is introduced into the measuring device cell 10 through the gas inlet 12.

(Calculation of catalyst activity (ik))
The rotating disk electrode was evaluated by performing cleanup, cycleric voltagram (CV) measurement, measurement of electrochemical surface (ECSA) before measurement, and measurement of electrochemical surface (ECSA) after measurement. Using the obtained oxygen reduction current (ORR current) measurement value (i) and limit diffusion current measurement value (iL), the mass transfer correction formula based on the Nernst diffusion layer model represented by the following general formula (1) Thus, the catalytic activity (ik) was calculated.

(In the general formula (1), i represents a measured value of oxygen reduction current (ORR current), iL represents a measured value of limiting diffusion current, and ik represents catalytic activity.)

  That is, according to the mass transfer correction formula based on the Nernst diffusion layer model, 1 / i = 1 / ik + 1 / L is established. This is transformed to solve the catalyst activity (ik) to obtain the general formula (1). The catalytic activity (ik) can be calculated from the measured value (i) of oxygen reduction current (ORR current) and the measured value of limiting diffusion current (iL).

(Calculation of mass activity)
Furthermore, the value obtained by dividing the calculated catalyst activity (ik) by the mass (μg) of active metal (such as platinum) in the catalyst ink layer of the disk electrode was defined as the mass activity of the electrode catalyst. That is, the catalytic activity per mass of active metal (such as platinum) present on the electrode surface was defined as “mass activity” and used as an indicator of the catalytic activity of the electrode catalyst.

  EXAMPLES Hereinafter, although an Example demonstrates this invention further more concretely, this invention is not limited to a following example.

<Example 1>
A rotating disk electrode was manufactured by the method for manufacturing a disk electrode for electrochemical measurement according to the present invention.
(Manufacture of catalyst ink)
8.3 mg of catalyst powder (manufactured by NE Chemcat Co., Ltd., Pt-supported carbon catalyst: trade name “SA50BK”: production lot A: Pt content 50.7 wt%) was weighed and sampled with 2.5 ml of ultrapure water. It put into the bottle and the catalyst powder slurry which consists of catalyst powder and ultrapure water was produced. The catalyst powder solution was produced by irradiating ultrasonic waves in order to maintain a good dispersion state of the catalyst powder in the catalyst powder solution.

  Next, 10 μL of ultrapure water and 20 μL of 10 wt% Nafion aqueous solution (trade name “DE1020CS” manufactured by Wako Chemical Co., Ltd.) were added to another container prepared in advance to prepare a Nafion-ultrapure aqueous solution. 2.5 ml of this Nafion ultrapure aqueous solution was weighed and slowly poured into a sample bottle containing the catalyst powder solution over about one minute. Thereafter, ultrasonic waves were applied for 15 minutes at room temperature, and the mixture was sufficiently stirred to obtain a catalyst ink.

(Production of disk electrode for electrochemical measurement)
10 μl of the catalyst ink in the sample bottle prepared above was collected using a micropipette while maintaining a good dispersion state of the catalyst powder. A clean rotating electrode (GC: made of glassy carbon, diameter 5 mmφ, area 19.6 mm ² ) was prepared, and the catalyst ink collected using a micropipette was dropped onto the surface. Thereafter, the catalyst ink was spread on the surface of the rotating disk electrode so as to have a uniform and constant thickness. Then, a coating film made of a catalyst ink was formed on the surface of the rotating disk electrode. The coating film made of this catalyst ink was allowed to stand. Thereafter, the coating film made of the catalyst ink was dried at a temperature of 23 ° C. and a humidity of 50% RH for 2.5 hours. The disk electrode provided with the coating film made of the dried catalyst ink was used as the electrochemical measurement disk electrode of the present invention.

  As shown in Table 1, the electrochemical measurement disk electrode of Example 1 had a catalyst amount of 7.44 μg and a platinum (Pt) mass of 3.77 μg in the catalyst ink layer on the rotating disk electrode. . The amount was calculated from the amount of catalyst ink introduced and the amount of catalyst ink dropped on the rotating disk electrode. The mass of platinum (Pt) in the catalyst ink layer was calculated from the composition of platinum and carbon of the catalyst particles.

<Examples 2 to 4>
In Example 2, a rotating disk electrode was produced in the same manner as in Example 1 except that the catalyst ink produced in Example 1 was used and the amount of catalyst ink dropped onto the rotating disk electrode was changed. Further, in Examples 3 and 4, as catalyst powders having different production lots, and thus different platinum contents, Pt-supported carbon catalyst manufactured by N.E. Chemcat Co., Ltd .: trade name “SA50BK” (lot “B”: Pt A rotating disk electrode was produced in the same manner as in Example 1 except that the content was 43.6 wt%.

<Comparative Examples 1 and 2>
Instead of the method for manufacturing the electrochemical measurement disk electrode of the present invention, the method for manufacturing the electrochemical measurement disk electrode (hereinafter referred to as “FCCJ method”) recommended by the Fuel Cell Practical Use Promotion Council (FCCJ) is adopted. A rotating disk electrode was manufactured. The method for manufacturing the electrochemical measurement disk electrode recommended by the FCCJ is that the catalyst ink contains monohydric alcohol and the drying condition of the catalyst ink layer is the method for manufacturing the electrochemical measurement disk electrode of the present invention. Is different. A Pt-supported carbon catalyst (trade name “SA50BK” manufactured by N.E. Chemcat Co., Ltd.) used as the catalyst powder was used as Comparative Example 1, and a product using Manufacturing Lot B was used as Comparative Example 2.

<Comparative Example 3>
In the method for producing the electrochemical measurement disk electrode of Example 2, a rotating disk electrode was produced in the same manner as in Example 2 except that the drying time was 16 hours in the step of drying the catalyst ink layer.

(Evaluation method of catalyst activity)
Using the electrochemical measurement disk electrodes manufactured in Examples 1 to 4 and Comparative Examples 1 to 3, the catalytic activity was evaluated as follows. Evaluation of the rotating disk electrode, 0.1 M of HCl0 ₄ as an electrolyte, Ag / AgCl saturated electrode as a reference electrode (RE) (RHE), rotating disc electrode measuring apparatus equipped with a Pt Pt mesh with black as a counter electrode (Hokuto Denko Co., Ltd., model HSV110, equipped with the company's rotating electrode control drive device) was used.

[Cleanup]
In the rotating disk electrode in the measuring device, after it soaked the rotating disk electrode HCl0 ₄ electrolyte solution, an electrolyte solution was purged for 30 minutes or more with argon gas. Thereafter, potential scanning was performed for 20 cycles under the conditions of a scanning potential of 85 to 1085 mV vs RHE and a scanning speed of 50 mV / sec.

[Evaluation of electrochemical surface (ECSA) before measurement]
Thereafter, potential scanning was performed for 3 cycles under conditions of a scanning potential of 50 to 1085 mV vs RHE and a scanning speed of 20 mV / sec.

[Oxygen reduction (ORR) current measurement]
After purging the electrolyte solution with oxygen gas for 15 minutes or more, a cycle potential voltagram (CV) under the conditions of a scanning potential of 135 to 1085 mV vs RHE, a scanning speed of 10 mV / sec, and a rotational speed of the rotating disk electrode of 1600 rpm. ) Measurement was performed. The current value at a potential of 900 mV vs RHE was recorded.

  Furthermore, the rotational speed of the rotating disk electrode was set to 400 rpm, 625 rpm, 900 rpm, 1225 rpm, 2025 rpm, 2500 rpm, and 3025 rpm, respectively, and ORR measurement was performed for each cycle.

[Evaluation of electrochemical surface (ECSA) after measurement]
Finally, a cyclic lick voltagram (CV) measurement was performed under the conditions of a scanning potential of 50 to 1085 mV vs RHE, a scanning speed of 20 mV / sec, and a cycle number of 3 cycles.

  Substance based on oxygen reduction current value (i) obtained above and limiting current value (iL) measured from cyclic lick voltagram (CV) and Nernst diffusion layer model represented by the following general formula (1) Based on the movement correction formula, the catalytic activity was calculated.

(In the general formula (1), i represents a measured value of oxygen reduction current (ORR current), iL represents a measured value of limiting diffusion current, and ik represents catalytic activity.)

  Furthermore, the calculation of mass activity (Mass Act) was calculated from the calculated value of catalyst activity (mA) and the value of Pt amount on the disk electrode. Table 1 below shows the manufacturing conditions of the disk electrodes of Examples and Comparative Examples, the measurement results of catalyst activity, and the calculation results of mass activity.

  In Examples and Comparative Examples shown in Table 1, the amount of catalyst ink (μg) on the disk electrode was the amount of catalyst ink dropped on the disk electrode by a collection container such as a pipette. Furthermore, the amount (μg) of Pt (platinum) on the disk electrode was calculated from the Pt (platinum) content in each catalyst particle (production lot “A” or production lot “B”). In Table 1, Examples 1, 2 and Comparative Example 1 using production lot A of the Pt-supported carbon catalyst used as the catalyst powder are group A, and Examples 3, 4 and Comparative Example using production lot B are used. Groups 3 and 4 were group B.

  In Table 1, the relative value of the mass activity indicating the catalyst activity (Mass Act) is calculated based on the mass activity (Mass Act) of the disk catalyst (Comparative Examples 1 and 2) manufactured by the “FCCJ method” (100%). did.

FIG. 4 is a graph showing the relative value (%) of the mass activity of the rotating disk electrode obtained in Example 1 when the mass activity standard (100) of the rotating disk electrode of Comparative Example 1 is used. FIG. 5 is a graph showing a relative value (%) of mass activity of the rotating disk electrode obtained in Example 3 when the mass activity standard (100) of the rotating disk electrode of Comparative Example 2 is used.

  According to Table 1, compared with the rotating disk electrode of Comparative Example 1, the rotating disk electrode of Example 1 has a measured oxidation-reduction current (ORR current) value (i) and a limiting diffusion current value (iL) of Comparative Example 1. It turned out to be larger than the rotating disk electrode. In Example 1 and Comparative Example 1, the mass activity of Example 1 calculated from the redox current (ORR current) measured value (i) and the limiting diffusion current value (iL) of the rotating disk electrode is It was revealed that the mass activity was about 1.6 times the mass activity. That is, the relative value (mass activity) of Example 1 based on the rotating disk electrode of Comparative Example 1 is 160%.

  From this, it is clearly understood that the catalytic activity of the catalyst electrode can be accurately measured by adopting the method for manufacturing an electrochemical disk electrode of the present invention and setting the manufacturing conditions.

  Similarly, in the rotating disk electrodes of Example 3 and Comparative Example 2, although the amount of Pt (platinum) on the disk electrode is substantially equal, the catalytic activity (ik) and mass activity of the disk electrode of Example 3 are It is about 2.5 times the value of the rotating disk of Comparative Example 2. That is, it was found that the relative value (mass activity) of Example 3 based on the rotating disk electrode of Comparative Example 2 was 254%.

  In Comparative Example 3, the disk electrode was manufactured under substantially the same conditions as in Example 4 except for the drying time in the step (iii) of drying the coating layer made of the catalyst ink. In the rotating disk electrodes of Example 4 and Comparative Example 3, the mass activity of the disk electrode of Comparative Example 3 is a comparative example of the mass activity of Example 4 even though the amount of Pt (platinum) on the disk electrode is substantially equal. The relative value based on the mass activity of 3 is 82%. Considering Example 4 and Comparative Example 3, even when the method for producing an electrochemical measurement disk electrode of the present invention is employed, the drying time is 10 hours in the step of drying the coating layer made of the catalyst ink. When it was over, it was found that the catalytic activity of the catalyst electrode could not be measured accurately.

  In the method for producing a disk electrode for electrochemical measurement according to the present invention, the catalyst layer formed on the surface of the catalyst electrode is coated on the entire surface of the catalyst electrode, the thickness of the catalyst layer is uniform, and the surface is smooth. Thus, it is possible to provide a disk electrode for electrochemical measurement in which the catalyst particle components in the catalyst layer are uniformly dispersed. Therefore, it is possible to precisely evaluate the catalytic activity inherent in the catalyst electrode. As a result, the method for producing an electrochemical measurement disk electrode according to the present invention can be applied not only to the electric equipment industry such as fuel cell automobiles and portable mobiles, but also to the catalytic activity of the catalyst electrode that can be applied to ENE-FARM, cogeneration systems, etc. It can be a technical standard that can be evaluated precisely and contributes to the development of the energy industry.

D rotating disk electrode method (RDE method) measuring device 10 measuring device cell 12 gas inlet 20 reference electrode (RE)
22 Reference electrode (RE) cell 30 Counter electrode (CE)
40 Rotating Disc Electrode 42 Electrode Base Material 44 Catalyst Particles X Catalyst Ink Layer 50 Solid Base 52 Support Portion 54 Oil Seal 60 Electrolyte

Claims (8)

A method of manufacturing a disk electrode for electrochemical measurement,
(i) a step of preparing a catalyst ink containing catalyst particles in which an active metal is supported on a carrier, a hydrogen ion conductive polymer electrolyte, and ultrapure water, and containing no monohydric alcohol;
(ii) dropping the catalyst ink on the surface of the disk electrode to form a coating layer made of the catalyst ink;
(iii) drying the coating layer made of the catalyst ink at 10 to 30 ° C .;
A method of manufacturing a disk electrode for electrochemical measurement, comprising: The specific resistance R of the ultrapure water is represented by the following general formula:
The method for producing a disk electrode for electrochemical measurement according to claim 1, wherein the specific resistance is 3.0 MΩ · cm or more.
In the above general formula, R represents specific resistance, and ρ represents electrical conductivity measured by a JIS standard test method (JIS K0552). The step (i) of preparing the catalyst ink includes
(ia) Mixing the catalyst particles and the ultrapure water to prepare a catalyst particle slurry,
(ib) A hydrogen ion conductive polymer electrolyte aqueous solution in which the hydrogen ion conductive polymer electrolyte and ultrapure water are mixed is prepared in advance,
(ic) The method for producing a disk electrode for electrochemical measurement according to claim 1 or 2, wherein the aqueous solution of hydrogen ion conductive polymer electrolyte is added to the catalyst particle slurry. In the catalyst particle slurry obtained in the step (ia),
The hydrogen ion conductive polymer electrolyte aqueous solution obtained in the step (ib) is added at an addition rate of 1.0 to 10.0 ml / min,
4. The method of manufacturing a disk electrode for electrochemical measurement according to claim 3, wherein a catalyst ink in which the catalyst particles are uniformly dispersed is prepared.   5. The electrochemical measurement disk according to claim 1, wherein the catalyst particles are contained in an amount of 0.05 to 1.0 part by weight with respect to 100 parts by weight of the catalyst ink. Electrode manufacturing method.   6. The electrochemical measurement according to claim 1, wherein the step of drying the catalyst ink layer is performed at a temperature of 10 to 30 ° C. and a humidity of 20 to 80% RH. Method of manufacturing disk electrode.   The method (10) for producing a disk electrode for electrochemical measurement according to any one of claims 1 to 6, wherein the step (iii) of drying the catalyst ink layer is performed for 2 to 6 hours.   The method for manufacturing a disk electrode for electrochemical measurement according to claim 1, wherein the disk electrode for electrochemical measurement is a rotating disk electrode.