CA2899131C - Carbon material for catalyst support use - Google Patents
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- B01J37/00—Processes, in general, for preparing catalysts; Processes, in general, for activation of catalysts
- B01J37/34—Irradiation by, or application of, electric, magnetic or wave energy, e.g. ultrasonic waves ; Ionic sputtering; Flame or plasma spraying; Particle radiation
- B01J37/341—Irradiation by, or application of, electric, magnetic or wave energy, e.g. ultrasonic waves ; Ionic sputtering; Flame or plasma spraying; Particle radiation making use of electric or magnetic fields, wave energy or particle radiation
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- H01M4/90—Selection of catalytic material
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Abstract
Description
Title of Invention: Carbon Material for Catalyst Support Use Technical Field [0001] The present invention relates to a carbon material which is used for a catalyst support and a method for producing the same.
Background Art
The diffusibility of the reaction starting materials to the catalyst metal which is dispersed inside the pores cannot necessarily be said to be good.
structures and which join with each other to form a network and discovered that this structure can be used as a support for supporting a catalyst (PLT 5). However, along with recent advances in technology, the environment of use of catalysts has become further harsher, so further improvements in durability and other aspects of performance have become necessary from catalyst supports as well.
Citations List Patent Literature
PLT 3: Japanese Patent Publication No. 2009-538813A
PLT 4: Japanese Patent Publication No. 2005-154268A
PLT 5: W02009/075264 Summary of Invention Technical Problem
Solution to Problem
structures of branched carbon-containing rod shapes or carbon-containing ring shapes, has a pore size of 1 to 20 nm and a cumulative pore volume of 0.2 to 1.5 cc/g found by analyzing a nitrogen adsorption isotherm by the Dollimore-Heal method, and has a powder X-ray diffraction spectrum which has a peak corresponding to a 002 diffraction line of graphite between diffraction angles (20: degrees) of 20 to 30 degrees and has a peak with a half value width of 0.1 degree to 1.0 degree at 25.5 to 26.5 degrees.
Advantageous Effects of Invention
Brief Description of Drawings
FIG. 2 is an enlarged view of an XRD image of a carbon material of Example 1 of the present invention and shows a method of measurement of a half value width.
FIG. 3 is an XRD image of a carbon material of Example 5 of the present invention.
FIG. 4 is an XRD image of a carbon material of Comparative Example 1 of the present invention.
FIG. 5 is an XRD image of a carbon material of Reference Example 3 of the present invention.
FIG. 6 is a scan electron microscope (SEM) image (magnification 100K) of a carbon material of Example 1 of the present invention.
FIG. 7 is a scan electron microscope (SEM) image (magnification 100K) of a carbon material of Comparative Example 4 of the present invention.
FIG. 8 is a scan electron microscope (SEM) image (magnification 100K) of a carbon material of Reference Example 3 of the present invention.
Description of Embodiments
to roughly separate the water content, then is divided into reaction tubes which are placed in a vacuum type electric furnace or vacuum type high temperature tank and heat treated at 60 C to 80 C in temperature, for example, for 12 hours or more. This being done, the silver acetylide segregates and metal-encapsulated dendritic nanostructures, in which metal silver particles is encapsulated, are formed.
By this, dendritic nanostructures of carbon (below, referred to as "mesoporous carbon nanodendrites" or simply "carbon nanodendrites") are obtained.
nitric acid aqueous solution may be used for washing repeatedly until the silver can be removed. The above obtained carbon nanodendrites themselves have sufficiently high specific surface areas, for example, 1500 m2/g or more.
may be used. Among these as well, argon is preferably used.
The dendritic structures can be observed by a scan electron microscope (SEM). The lengths of this dendritic parts are usually 50 to 300 nm, while the diameters of the dendritic parts are 30 to 150 nm or so.
However, the pores of the carbon material for catalyst support use of the present invention are formed by nanoscale explosive reactions which cause eruption of encapsulated silver. The pores mainly form continuous mesopores. When supporting the catalyst metal particles inside pores, generally, the particle size is several nanometers, but in the carbon material for catalyst support use of the present invention, sufficient space is secured for diffusion of the reaction substances and reaction products inside the pores. On the other hand, even if the BET specific surface area is the same, in the case of activated carbon, the pores are not continuous, so even if supporting catalyst metal particles, it is difficult and insufficient for the reaction substances and reaction products to diffuse inside the pores.
Catalyst metal particles which are usually prepared to diameters of several nm (2 to 10 nm) are dispersed inside the pores in a state of high dispersion. If the metal particles are held in cylindrical shaped pores, combination of catalyst particles with each other and peeling off are suppressed. This is believed to contribute to longer catalyst lifetime. Note that, there are several analytical techniques for calculating the pore size and cumulative pore volume, but they can be calculated by analyzing the adsorption isotherm of the adsorption process by the Dollimore-Heal method (DH
method).
Furthermore, by dividing the 10% amount of steam adsorption by the BET value, expression as a standardized indicator of the hydrophilicity per unit surface area becomes possible. If the Q-value is smaller than 0.05x10-3, the protonic conduction resistance at the time of operation under low moisture conditions becomes large, so the overvoltage becomes larger, so this is not suitable for the cathode of a polymer electrolyte fuel cell. If the Q-value is larger than 1.0x10-3, the hydrophilicity is too high, so when operating under high humidity conditions, the so-called "flooding phenomenon" will occur and power can no longer be generated.
Further, simultaneously, catalyst performance excellent in diffusibility of the reaction starting materials and reaction products can be exhibited because of the amorphous structures comprised of nanosize graphene derived from the mesoporous pore structures. The biggest feature of the carbon material of the present invention is the possession of a structure in which both grown graphene stacked structures and nanosize graphene amorphous structures are copresent. The grown graphene stacked structures are specifically evaluated by the presence of the peak at 25.5 to 26.5 degrees in the X-ray diffraction. The line width is 0.1 to 1.0 degree. If smaller than 0.1 degree, the stacked structures grow too much, so the pores end up being crushed and the gas diffusibility can no longer be maintained. If larger than 1.0 degree, the stacked structures do not sufficiently grow, so the consumption by oxidation ends up becoming remarkable and a harsh operating environment can no longer be withstood. Further, amorphous structures comprised of nanosize graphene are shown by the presence of a broad peak between 20 to 30 degrees. If this broad peak (corresponding to 002 diffraction line of graphite) is not present, it means the structures are comprised of irregular carbon not containing even nanosize graphene, mesoporous structures are not maintained, and the gas diffusibility ends up falling.
Examples
For the structure of the carbon material, a Hitachi High Technologies field emission scanning electron microscope (SEM) Model SU-9000 was used to examine the shape and confirm the presence of carbon nanodendritic structures.
specific surface area pore size and cumulative pore volume, a Quantachrome Instruments Autosorb Model I-MP
was used. The pore size and cumulative pore volume were calculated by analyzing the adsorption isotherm of the adsorption process by the Dollimore-Heal method (DH
method). The analysis program built in the apparatus was used to calculate the cumulative pore volume (cc/g) between the pore sizes 1.0 to 20 nm.
120 C and 1 Pa or less for 2 hours, were held in a 25 C
constant temperature tank, and were gradually supplied with steam from a vacuum state to a saturated vapor pressure of steam at 25 C to change the relative humidity in stages. The amounts of steam adsorption were measured there.
Q-value).
to 200 C in temperature and held at that temperature for minutes (first heat treatment). While holding it, nanoscale explosive reactions occurred and the silver erupted whereby an intermediate product comprised of carbon with silver deposited on its surface was obtained.
20 [0044] This intermediate product was washed by concentrated nitric acid for 1 hour to dissolve away the silver which remained at the surface etc. as silver nitrate and to dissolve away unstable carbon compounds.
The intermediate product from which these were dissolved away was rinsed, then placed in a graphite crucible and heat treated in an argon atmosphere in a graphitization furnace at 1600 C for 2 hours (second heat treatment) to obtain a carbon material for catalyst support use. An example of the XRD of the carbon material which was obtained in Example 1 is shown in FIG. 1. An enlargement of the extent of angle of FIG. 1 is shown in FIG. 2. From the chart of FIG. 2, the peak position and half value width of the peak were found. As a result, the peak position was 25.9 degrees and the half value width was 0.7 degree. An SEM image of the carbon material which was obtained in Example 1 is shown in FIG. 6. The diameter of the dendritic part was about 60 nm, while the length was 130 nm.
[0045] Example 2 Except for making the temperature of the second heat treatment 1800 C, the same procedure was performed as in Example 1 to obtain a carbon material.
[0046] Example 3 Except for making the temperature of the second heat treatment 2000 C and making the treatment time 0.5 hour, the same procedure was performed as in Example 1 to obtain a carbon material.
[0047] Example 4 Except for making the heating time of the second heat treatment 2 hours, the same procedure was performed as in Example 3 to obtain a carbon material.
[0048] Example 5 Except for making the heating time of the second heat treatment 4 hours, the same procedure was performed as in Example 3 to obtain a carbon material. An example of the XRD of the carbon material which is obtained at Example 5 is shown in FIG. 3.
[0049] Example 6 Except for making the temperature of the second heat treatment 2200 C, the same procedure was performed as in Example 1 to obtain a carbon material.
[0050] Comparative Example 1 Except for making the temperature of the second heat treatment 200 C, the same procedure was performed as in Example 1 to obtain a carbon material. An example of the XRD of the carbon material which is obtained at Comparative Example 1 is shown in FIG. 4.
[0051] Comparative Example 2 Except for making the temperature of the second heat treatment 800 C, the same procedure was performed as in Example 1 to obtain a carbon material.
[0052] Comparative Example 3 Except for making the temperature of the second heat treatment 1200 C, the same procedure was performed as in Example 1 to obtain a carbon material.
[0053] Comparative Example 4 Except for making the temperature of the second heat treatment 2600 C, the same procedure was performed as in Example 1 to obtain a carbon material. A SEM image of the carbon material which is obtained at Comparative Example 4 is shown in FIG. 7.
[0054] As reference examples, samples of the carbon material ketjen black (made by Lion, trade name: EC600JD) used in the past as a catalyst support of a polymer electrolyte fuel cell were prepared. Samples with no heat treatment (Reference Example 1), samples with heat treatment at 1800 C (Reference Example 2), and samples with heat treatment at 2000 C (Reference Example 3) were processed by methods similar to the examples and were similarly measured for BET specific surface area S, cumulative pore volume, Vio/S (Q value), and presence of dendritic structures.
[0055] As shown in Table 1, Examples 1 to 6 have structures which have both suitably grown stacked structures of graphene and amorphous structures comprised of nanosize graphene derived from the mesoporous pore structures. Furthermore, these carbon materials have dendritic structures. By combination with the amount of steam adsorption per unit area expressed by the Q-value, the catalyst dispersability is good and the moisture retention characteristic of the catalyst layer when made into a cell becomes a range suitable for operation in a low moisture environment. On the other hand, in Comparative Examples 1 to 3, there were dendritic structures, but the graphene was insufficiently stacked, while in Reference Examples 1 to 3, there were no dendritic structures and, judging from the shape of the X-ray diffraction spectrum and value of the Q-value, it was learned that the dispersability of the catalyst and the diffusibility of the gas or the water produced when made into a fuel cell are not sufficient compared with the carbon material of the present invention.
[0056] Evaluation Test of Catalyst Using the example of a hydrogenation catalytic reaction, the carbon materials of Examples 1 to 6 and Comparative Examples 1 to 4 were used as catalyst supports to prepare metal-containing catalysts. The durability as a fuel cell was evaluated in the following way. Platinum was used as the catalyst seed, and the cell performance was evaluated using a fuel cell measurement apparatus for initial performance and results in a cycle deterioration test.
The results of evaluation are shown in Table 1.
[0057] A chloroplatinic aqueous solution and polyvinyl pyrrolidone were placed in distilled water and stirred at 90 C while pouring in sodium borohydride dissolved in distilled water so as to reduce the chloroplatinic acid.
To this aqueous solution, the carbon material of each of Examples 1 to 6 and Comparative Examples 1 to 4 was added and stirred for 60 minutes, then filtered and washed. The obtained solids were dried at 90 C in vacuum, then pulverized and heat treated in a hydrogen atmosphere at 250 C for 1 hour to thereby prepare a catalyst for fuel cell use. Further, the amount of supported platinum of the catalyst was adjusted to 30 mass%.
[0058] The particle size of the platinum particles was estimated by the formula of Scherrer from the half value width of the platinum (111) peak in the powder X-ray diffraction spectrum of the catalyst obtained by using an X-ray diffraction apparatus (made by Rigaku, RAD).
[0059] The catalyst was added in a stream of argon to a 5%-Nafion solution (made by Aldrich) to give a mass of the Nafion solids of 3 times the mass of the catalyst.
The mixture was lightly stirred, then ultrasonic waves were used to crush the catalyst. Butyl acetate was added while stirring to give a solids concentration of the platinum catalyst and Nafion combined of 2 mass% arid thereby prepare a catalyst layer slurry.
[0060] The catalyst layer slurry was coated on a single surface of a Teflon sheet by the spray method and dried in an 80 C stream of argon for 10 minutes, then dried in a 120 C stream of argon for 1 hour to obtain an electrode sheet with a catalyst contained in the catalyst layer. Further, the spray conditions etc. were set so that the electrode sheet had an amount of platinum used of 0.15 mg/cm2. The amount of platinum used was found by measuring the dry mass of the Teflon sheet before and after spraying and calculating the difference.
[0061] Furthermore, two 2.5 cm square size electrodes each were cut out from the obtained electrode sheet, two of the same type of electrodes were placed sandwiching an electrolyte film (Nafion 112) so that the catalyst layers contacted the electrode film, and the assembly was hot pressed at 130 C and 90 kg/cm2 for 10 minutes. The assembly was cooled in this state down to room temperature, then only the Teflon sheets were carefully peeled off so that the catalyst layers of the two electrodes (below, anode and cathode) were fixed to the Nafion film. Furthermore, commercially available carbon cloth (made by ElectroChem, EC-CC1-060) was cut into two sheets of 2.5 cm square size which were placed sandwiching the anode and cathode fixed to the Nafion film and the assembly was hot pressed at 130 C and 50 kg/cm2 for 10 minutes to prepare four types of membrane electrode assemblies (MEA).
[0062] The prepared MEAs were loaded into commercially available fuel cell measuring devices and measured for cell performance. The cell performance was measured by changing the voltage between cell terminals from the no-load voltage (normally 0.9 to 1.0V) to 0.2V in stages and measuring the current density when the voltage between cell terminals is 0.8V. Further, as the durability test, a cycle of holding the assemblies at the no-load voltage for 15 seconds and holding the voltage across the cell terminals at 0.5V for 15 seconds was performed 4000 times, then the cell performance was measured in the same way as before the durability test. For the gas, air was supplied to the cathode and pure hydrogen as supplied to the anode to give rates of utilization of respectively 50% and 80%. The respective gas pressures were adjusted to 0.1 MPa by backing pressure valves which were provided downstream of the cell. The cell temperature was set to 70 C, while the supplied air and pure hydrogen were respectively bubbled in distilled water which was warmed to 50 C to wet them. The cell characteristics were evaluated by the amount of current (mA/cm2) per platinum unit area. The durability of the cell was evaluated by the rate of drop. The rate of drop was calculated by the following formula.
Rate of drop (%)={(Initial characteristic-Characteristic after deterioration)/ Initial characteristic}x100 [0063] As shown in Table 1, the rates of drop in current of cells using the carbon materials which were obtained in the present invention (Examples 1 to 6) as catalyst supports are extremely small compared with Comparative Examples 1 to 4. This result shows that by using the carbon material for catalyst support use of the present invention, the initial performance was maintained while the durability of the cell was improved. This improvement in the rate of drop of current is believed to be a result of the carbon material for catalyst support use of the present invention having a structure where both stacked structures of graphene and amorphous structures comprised of nanosize graphene are copresent.
[0064] Coke, carbon fiber, activated carbon, and other easily graphitizable carbon materials made using pitch as a starting material transform to graphite if heated to a high temperature. Graphite is generally high in oxidation resistance, so using graphite for a support is effective for improvement of the durability of a cell. On the other hand, there are the problems that in the process of heat treatment, the graphite crystal structure becomes rearranged, a fall occurs in the BET specific surface area which is required for the dispersion of the catalyst, and the pore structures end up being crushed.
For this reason, in PLT 1, to compensate for the crushing of pores when using activated carbon constituted by a precursor of easily graphitizable carbon, the practice has been to pretreat the carbon in advance to activate it to a high degree, secure a large BET surface area, then secure the pore structures after heat treatment. The present invention uses dendritic carbon material comprised of nanosize graphene as a starting material and heat treats this (second heat treatment) to impart a structure having both suitably grown graphene stacked structures and amorphous structures comprised of nanosize graphene derived from the mesoporous pore structures. For this reason, unlike the carbon material of PLT 1, when used as a support, it is possible to secure gas diffusibility and catalyst activity derived from nanosize graphene and thereby otherwise secure initial performance and doubly achieve durability, so a high cell performance is exhibited.
[0065] The carbon material of the present invention is a material which is effective not only for applications of a metal-carrying catalyst support which is introduced here, but also fields in which diffusibility of the gas or liquid is demanded, for example, activated carbon electrodes for electric double-layer capacitor use, air electrodes of lithium air secondary batteries, etc.
[0066] Table I
Treat- Time BET Pore Vio/S Dendritic XRD (26 Half Platinum Initial Character- Rate of ment specific volume (Q
value) structure degree peak value particle character- istic after drop temp. surface present?) width size istic deteriora-area S tion C hr mz/g cc/g ml/m2 Degree nm mA/cm2 mA/cm2 %
Example 1 1600 2 1200 1.0 0.5 x 10-3 Maintained Yes 0.7 3.8 165 153 7.2 Example 2 1800 2 1000 1.0 0.2 x 10-3 Maintained Yes 0.5 3.5 175 165 5.7 Example 3 2000 0.5 650 0.7 0.2 x l0 Maintained Yes 0.3 3.7 165 155 6.1 Example 4 2000 2 600 0.7 0.2 x 10 3 Maintained Yes 0.3 3.7 160 150 6.3 Example 5 2000 4 500 0.7 0.2 x 10 3 Maintained Yes 0.3 3.8 160 148 7.5 Example 6 2200 2 300 0.5 0.1 x 103 Maintained Yes . 0.2 3.7 155 145 6.3 P
Comp. Ex. 1 200 2 1325 1.2 1.2 x 10-3 Maintained No 3.4 170 130 , 23.5 0 I., Comp. Ex. 2 800 2 1350 1.2 1.1 x 103 Maintained No - 3.7 165 140 . 15.2 0 w Comp. Ex. 3 1200 2 1300 1.1 0.9 x 103 Maintained No 3.6 170 156 8.2 w w Comp. Ex. 4 2600 2 120 0.1 0.01 x 10-3 None Yes 0.2 Poor support of catalyst 1-I., (aggregated) I Ref. Ex. Ex. 1 - 1280 1.3 0.4 x 10-3 None No 3.6 3.6 3.6 3.6 T
Ref. Ex. 2 1800 2 450 0.8 0.02 x 10-3 None No - 3.9 3.9 3.9 3.9 Ref. Ex. 3 2000 2 340 0.5 0.02 x 10-3 None No - 4.0 4.0 4.0 4.0 w I
Claims (4)
(V10) and a nitrogen adsorption BET specific surface area (m2/g) of the carbon material (S) is 0.05x10-3 to 1.0x10-3.
a step of preparing a solution which contains a metal or a metal salt, a step of blowing in acetylene gas in a state of applying ultrasonic waves to said solution and producing dendritic carbon nanostructures comprising branched rod shapes or ring shapes which are comprised of a metal acetylide which contains said metal, a step of heating said dendritic carbon nanostructures at 60°C to 80°C in temperature, causing segregation of said metal of said metal acetylide, and producing metal-encapsulated dendritic carbon nanostructures in which said metal is encapsulated in said dendritic carbon nanostructures, a step of heating said metal-encapsulated dendritic carbon nanostructures to 160°C to 200°C, causing said metal to erupt, and producing dendritic carbon mesoporous structures which have a large number of mesopores at the surface and inside, and a step of heat treating said dendritic carbon mesoporous structures under a reduced pressure atmosphere or under an inert gas atmosphere at 1600°C to 2200°C for 0.5 hour to 4.0 hours.
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| PCT/JP2014/054228 WO2014129597A1 (en) | 2013-02-21 | 2014-02-21 | Carbon material for use as catalyst carrier |
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