CA3019718A1 - Fuel cell catalyst support based on doped titanium suboxides - Google Patents
Fuel cell catalyst support based on doped titanium suboxides Download PDFInfo
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M4/00—Electrodes
- H01M4/86—Inert electrodes with catalytic activity, e.g. for fuel cells
- H01M4/90—Selection of catalytic material
- H01M4/92—Metals of platinum group
- H01M4/925—Metals of platinum group supported on carriers, e.g. powder carriers
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M4/00—Electrodes
- H01M4/86—Inert electrodes with catalytic activity, e.g. for fuel cells
- H01M2004/8678—Inert electrodes with catalytic activity, e.g. for fuel cells characterised by the polarity
- H01M2004/8689—Positive electrodes
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M8/00—Fuel cells; Manufacture thereof
- H01M8/10—Fuel cells with solid electrolytes
- H01M2008/1095—Fuel cells with polymeric electrolytes
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E60/00—Enabling technologies; Technologies with a potential or indirect contribution to GHG emissions mitigation
- Y02E60/30—Hydrogen technology
- Y02E60/50—Fuel cells
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Abstract
The fuel cell electrocatalyst includes the support structure. The support structure includes at least one titanium suboxide, a first dopant and a second dopant. The first dopant is a metal and the second dopant is a Group IV element. The fuel cell electrocatalyst also includes a metal catalyst deposited on the support structure.
Description
SUBOXIDES
FIELD
[0001] This disclosure relates generally to fuel cell electrocatalysts, and more specifically to fuel cell electrocatalysts having support structures based on doped titanium suboxides.
BACKGROUND
However, carbon can be a liability when it comes to durability since it is prone to corrosion under the highly acidic and oxidative operating conditions of a PEM fuel cell.
Carbon corrosion can be detrimental to the long-term performance of a fuel cell.
Furthermore, even when carbon corrosion does not occur, Pt aggregation can occur on carbon, which decreases the electrochemically active surface area (ECSA) of the catalyst, and subsequently the performance of the electrode. This is particularly evident during prolonged open-circuit potential (OCP) or under repeated start¨stop cycles.
fuel cells with a corrosion stable support.
, ,
SUMMARY
BRIEF DESCRIPTION OF THE DRAWINGS
electrocatalyst.
support structure.
support structure.
elecrocatalyst.
electrocatalyst.
support structure.
bias potential of 0.425 V vs. RHE.
recorded in N2-purged 0.5 m H2SO4 at 25 C and a scan rate of 10 my s-1.
recorded in 02-saturated 0.5 m H2504 at 25 C and a scan rate of 5 my s-1 and 900 rpm.
,
during the AST
with measurements being made in N2-purged 0.5 m H2SO4 (aq) at 25 C at a sweep rate of 50 my s-1.
during the AST, shown as Nyquist plots.
during the AST, shown as capacitance plots.
catalysts before and after the 5000 cycle AST.
catalysts before and after the 5000 cycle AST.
at 80 C, using a Pt loading of 0.2 mg cm-2, H2 flow rate of 100 nml min-1 100% rh 1 bar bp; 02 flow rate 200 nml min-1 100% rh 1 bar bp, and membrane = NRE212.
where data being obtained at the beginning of life (BOL) and after 150 h and 250 h of , , testing and shown as (a) power density and (b) polarization curves with measurements being made in a 5 cm2 single cell PEMFC at 80 C, using a Pt loading of 0.2 mg CM-2, H2 flow rate of 100 nml min-1 100% rh 1 bar bp; 02 flow rate 200 nml min-1 100%
rh 1 bar bp, and membrane = NRE212.
DESCRIPTION OF EXAMPLE EMBODIMENTS
No embodiment described below limits any claimed subject matter and any claimed subject matter may cover apparatuses and methods that differ from those described below. The claimed subject matter are not limited to apparatuses, methods and compositions having all of the features of any one apparatus, method or composition described below or to features common to multiple or all of the apparatuses, methods or compositions described below. It is possible that an apparatus, method or composition described below is not an embodiment of any claimed subject matter. Any subject matter that is disclosed in an apparatus, method or composition described herein that is not claimed in this document may be the subject matter of another protective instrument, for example, a continuing patent application, and the applicant(s), inventor(s) and/or owner(s) do not intend to abandon, disclaim, or dedicate to the public any such invention by its disclosure in this document.
Also, the description is not to be considered as limiting the scope of the example embodiments described herein.
is intended to represent an inclusive - or. That is, "X and/or Y" is intended to mean X or Y
or both, for example. As a further example, "X, Y, and/or Z" is intended to mean X or Y or Z or any combination thereof.
Mo catalyst showed enhanced ORR activity and durability despite the support still having a sizable band gap (2.6 eV). However, in spite of the technologies that have been developed, there remains a need in the field for improvements in the development of fuel cell catalyst supports.
The process of forming the catalyst support structure involves the use of sequential doping of TiO2 with two different elements to create oxygen vacancies within the lattice of the metal oxide. The resulting dual-doped suboxide has a substantially lower band gap, which is lower than doping with just a single element, rendering it suitable for use in electrochemical devices.
The second dopant can be a Group IV element. For instance, the second dopant can be silicon (Si). More specifically, the support structure can be a Ti305-Moo2Sio.4 (TOMS) support structure and be used in various applications including, but not limited to, as a fuel cell catalyst support structure.
Mo-based support structure.
catalyst" will refer to a TOMS support structure with platinum or a platinum-based alloy arranged thereon.
of its active surface area over the 5000 cycle accelerated stress test.
pattern obtained from the TOMS support structure. The presence of Mo appears to favor the formation of the titanium suboxides in a reducing environment that creates Ti cation oxygen vacancies or stoichiometric reduction of Ti4+ to Ti3+. The corresponding diffractogram shows that the support structure consists of a mixture of Ti305 phases with the main characteristic reflection at 26 = 25.51 , {110) and Ti60 at 26 =
39.65, with Ti305 being the prevailing phase. Mo is present either as metallic Mo (ICDD card no.
2331) or M002 (ICDD card 00-021-0569). The M002 appears to have a rutile-type crystal structure, in which M06 octahedra share cores and edges. M002 has high electronic conductivity due to the short metal¨metal bond distance along the direction of edge sharing. Both metallic Si (ICDD card no. 01-078-2500) and 5i02 (ICDD card no.
1242) can be identified.
40.61 {111}, 46.92 {200}, 68.1 {220}, and 81.81 {311}, and 86.43 {222}. All corresponding Pt peaks were shifted toward higher angles, indicating a diminution of the lattice spacing. This phenomenon may be attributed to the strong interaction between Pt and the TOMS
support structure. Moreover, the peak at 20 = 40.61 appears broad and intense, which may signify that the Pt NPs are greatly oriented towards the Pt {111} plane, which is the most stable and highly active toward the ORR which contains hexagonally packed Pt atoms and does not undergo surface reconstruction, unlike Pt {100} and Pt {110}
surfaces. The size of Pt crystallites over the TOMS and carbon supports was calculated from the width of the {220} and {222} peaks using the Scherrer¨Debye equation, resulting in a mean crystallite size of Pt equal to 4 and 2.5 nm for Pt/TOMS and Pt/C
electrocatalysts, respectively.
support structure measured through the absorption spectra of the diffuse reflectance of both the materials. The reflectance data has been converted into the absorption coefficient values followed by the creation of a Tauc plot. The band gap of the TOMS support structure was measured to be 0.31 eV, which appears to be lower than those of commercial TiO2 (3.35 eV) and Ti305¨Mo (2.6 eV). These measurements appear to indicate that the TOMS
support structure has conductivity approaching that of a metal conductor.
Table 1: Band gap and electronic conductivity of TiO2, Ti305¨Mo and TOMS
Band gap (eV) Electronic conductivity (S cm') TiO2 3.35 1.4 x 10-6 Ti305-Mo 2.6 [ref. 17] 0.004 TOMS 0.31 0.11 Carbon black 0.83
(see FIG. 2A).
Also, the Ti double peaks of 2p1/2 and 2p3/2 levels were located at binding energies of 464.67 eV and 458.97 eV, respectively. Pure TiO2 shows the Ti double peaks of 2p1/2 and 2p3/2 levels at 464.2 eV and 458.5 eV binding energies, while the reduced form (e.g.
Magneli phase) has binding energies of 464.7 eV and 459.0 eV. The shift in the Ti 2p levels compared to defect-free TiO2 is caused by surface oxygen vacancy defects in the TOMS support structure. The incorporation of Mo and Si into the TiO2 lattice appears to create these oxygen vacancies resulting in the change of energy difference between the conduction and valence bands. Therefore, the shifting of Ti 2p levels towards higher binding energies may be attributed to the reduced Ti due to combined effects between molybdenum and Si with TiO2 which resulted in oxygen vacancies and Ti suboxide formation.
2B): Mo is largely present in the form of MoOx on the surface of the TOMS
support structure, with traces of metallic Mo. The Si spectrum has peaks associated with Si4+ and Si (see Fig. 2C): also, Si is largely present in the form of SiOx on the surface of the TOMS
support structure (in agreement with XRD analysis), with traces of metallic Si on the surface. The Pt analysis appears to demonstrate spin¨orbit splitting doublet peaks in the 4f region referring to 4f7/2and 4f512, where the deconvolution of the Pt spectrum reveals two pairs of doublet peaks in each region. The high intensity doublet peaks at the binding energies of 71.75 eV and 75.1 eV, respectively, appear to be attributed to metallic Pt (Pt ). The low-intensity doublet peaks at binding energies of 72.95 eV and
species due to surface oxide/hydroxide (see FIG. 2D). The binding energy of 71.75 eV
for Pt0 4f7/2 reveals 0.75 eV positive shifts towards higher binding energy compared to the 4f7/2 conventional value of Pt/C. This shift to higher binding energy corresponds to induced positive charge on the dispersed Pt NPs due to the interaction between Pt NPs and the TOMS support structure which positively influenced the d-band state of Pt NPs.
This effect, which is also in line with the XRD results, shows an enhanced interfacial strong electronic interaction between the TOMS support structure and Pt NPs.
This electron donation from the TOMS support structure to Pt NPs, due to the strong metal¨
support interaction (SMSI), is expected to enhance the electroactivity of Pt/TOMS.
[0076] FIG. 3 displays SEM images of Pt/TOMS, along with the corresponding energy dispersive X-ray spectra (EDX). The particles are spherical in nature, and fairly homogeneous in their shape and composition. The EDX spectrum confirms the presence of Si and Mo in the Pt/TOMS electrocatalyst.
support structure appears to remain stable, showing virtually no change over the course of 5000 cycles, giving no indication of Ti, Mo, and Si oxidation/corrosion.
catalysts. Both electrocatalysts exhibit the classical Pt CV shape, three anodic peaks and two cathodic peaks with good reversibility in the hydrogen region assigned to the uniformly dispersed polycrystalline Pt NPs over the surface of the TOMS
support structure. The Pt/TOMS showed earlier reduction of adsorbed Pt oxides compared to Pt/C. The ECSA of each electrocatalyst was determined by integrating the charge associated with HUPD (210 pC cmpt -2), and the values are listed in Table 2.
Also listed in Table 2 are the reported ECSA values for several other catalysts that employ metal oxide-based supports. The Pt/TOMS catalyst had a very high ECSA value of 87 m2 gpt-1, which is one of the highest values reported in the literature for metal oxide containing supports. This confirms that catalyst particles are well dispersed onto the TOMS support structure. Furthermore, it also indicates that the catalyst layer created from Pt/TOMS
creates a very high degree of accessibility to Pt active sites.
Table 2: Electrochemical characterization of electrocatalysts Pt ECSA I 0.9 *0.9 ECSA loss, cycle, Catalyst [mg cm-2] Cm2g-il imA [mA cm-2] Media scan rate [rn1/ s-1 Ref.
Pt/TOMS 0.025 87.33 66.5 1.57 0.5 M H2SO4 10.2%, 5000, 50 Current study PVC 0.03 98.67 31.7 0.95 0.5 M H2SO4 79.4%, 5000, 50 Current study Ptr11305-Mo 0.015 22.3 55.2 1.1 0.5 M I-I2SO4 11.2%, 5000, 50 17 Pt/Ti0 76405,302 0.221 81.07 3.17 0.65 0.5 M 1-12804 -0.075 34.7 3.4 0.2 0.5 M H2SO4 58.8%, 5000, 20 68 Ptrri02-CN., 75 zt 10 0.5 M H2SO4 3%, 1000, Ptirio.,Moo302 0.221 72.5 0.8 0.5 M 112804 -Pt/Ta-TiO2 0.038 36.5 21 0.45 0.1 ttl HC104 26.3%, 10000, 20 69 Pt/Nb-Ti02. 0.087 36 2.4 0.15 0.1 M HC104 25%, 1000, 100 70 Pt/1'1107 0.0478 6 5.33 0.2 0.1 M FIC104 28%, 1000, 20 71
cm-2 at 0.9 V vs. RHE compared to only 0.95 mA cm-2 for Pt/C. Furthermore, this appears to represent an improvement over the ORR activity reported for Pt/Ti305-Mo (1.1 mA cm -2 at 0.9 V). Such an enhancement in ORR activity may correlated with the change in the Pt-Pt interatomic distance. In fact, the distinctive electroactivity of Pt/TOMS compared to Pt/C is defined through changes in the Pt d-band length and smaller lattice parameter values induced by the metallic suboxide support and formation of hydrogen molybdenum bronze, which effectively promotes the direct 4-electron transfer ORR on the Pt/TOMS.
The reduction of the Pt d-bond length is due to the SMSI between the TOMS
support structure and Pt NPs that weakens the interaction between Pt and the adsorbed oxygenated species that leads to higher electroactivity of Pt/TOMS compared with that of the commercial Pt/C catalyst. Since the TOMS support structure makes a stable Pt NP
surface at high electrochemical potentials, the Pt/TOMS appears to possess a lower kinetic barrier for the ORR compared to Pt/C which is a key kinetic parameter for ORR
activity. A summary of key electrochemical parameters and a comparison to the ORR
activity of other catalysts that employ metal oxide based supports is shown in Table 2.
and commercial Pt/C electrocatalysts to 5000 potential cycles in the range of 0.05-1.25 V vs.
RHE. Referring now to FIG. 7, shown therein is a comparison of the change in the CV
response with potential cycling for each catalyst. As the test progressed, the Pt/TOMS
remained quite stable, while the Pt/C decayed rapidly (see FIGS. 7A and 7B).
For the Pt/TOMS electrocatalyst, the decay in ECSA after 5000 ASTs was 10.2% while Pt/C
showed an ECSA decay of 79.4%. This durability for the Pt/TOMS catalyst appears to be a result of the ability of the support structure to mitigate the segregation of Pt NPs, which implies that Pt NPs anchor to the surface of the TOMS support structure through the SMSI
that leads to improvement in both electroactivity and stability of the Pt catalyst.
electrocatalysts, shown as Nyquist and capacitance plots. The Nyquist and capacitance plots obtained for Pt/TOMS were virtually unchanged over the course of the AST. This appears to indicate that excellent ionic and electronic conductivities were maintained throughout the test, and that there was no decay or corrosion of the TOMS
support structure. For the Pt/C catalyst, a small increase in the Warburg length was observed over the course of the AST, indicating a small increase of the catalyst layer resistance due to carbon corrosion. The capacitance plots for Pt/C showed an initial increase in limiting capacitance, which is most likely due to incomplete wetting of the Pt/C
electrocatalyst surface at the initial stage of the measurements. Upon cycling, the capacitance plots for Pt/C showed decrease in limiting capacitance, which is the characteristic response when Pt dissolution and agglomeration are the dominant degradation mechanisms.
activity was reassessed repeatedly for both electrocatalysts after the completion of the AST procedure protocol (see FIG. 9). As expected, there was very little change in ORR
activity for the Pt/TOMS catalyst, while a decline in ORR activity was observed for Pt/C due to sintering and agglomeration of Pt NPs. These results appear to show that the Pt/TOMS
catalyst layer remained stable over the course of the AST and there was essentially no change in the elemental distribution of the Pt/TOMS catalyst layer components after the AST.
electrodes with that obtained using Pt/C electrodes. The Pt/TOMS and Pt/C
electrodes produced a maximum power density of 973 and 865 mW cm-2, respectively. This is consistent with the obtained results from ORR activity and appears to demonstrate that the Pt/TOMS catalyst material is more durable than Pt/C and outperforms Pt/C
catalysts at the beginning of life. The power density of Pt/TOMS appears to be associated with the charge transfer between Pt and the TOMS support structure which appears to cause the enhancement of the oxygen reduction kinetics. The obtained results confirmed that the support material influences the activity of electrocatalysts by promoting the diffusion of reactants and products, and this translates into higher performance in an operating fuel cell. Moreover, the stability of Pt/TOMS MEA was assessed over the course of 250 hours of operation. FIG. 11 shows a comparison of the fuel cell performance at the start of the test to that obtained at the end of 250 hours. Minimal change in the performance was observed, with the polarization curves being virtually unchanged. This demonstrates that Pt/TOMS remained stable during the durability test and enhanced stability of the TOMS
support structure translates into better long-term performance in an operating fuel cell.
catalyst demonstrates improved electrocatalytic activity and stability of the oxygen reduction reaction, which is a key reaction in polymer electrolyte membrane fuel cells (PEMFC).
materials. Metal catalysts deposited on TOMS suitable for use in direct alcohol fuel cells, including direct methanol and direct ethanol fuel cells, may include but are not limited to, Pt-Ru/TOMS and Pt-Sn/TOMS.
suitable for use in formic acid fuel cells may include but are not limited to Pd/TOMS.
breathalyzers) and glucose sensors.
EXAMPLES
NH3 basis, polyvinylpyrrolidone (PVP40: (C6H9N0), average molar weight 40 000), poly(ethylene glycol)-b/ock-poly(propylene glycol)-b/ock-poly(ethylene glycol) (Pluronic 123, average molar weight 5800), sulfuric acid (H2SO4) 95-98 wt%, Naflon perfluorinated resin solution 5 wt%, acetone (CH3-COCH3) 99.5 wt%, 2-propanol (C3I-180) 99.5 wt%, ammonium molybdate (H24M07N6024.4H20), Silicon nano-powder (Si) 98%, were purchased from Sigma-Aldrich. A commercial platinum catalyst 20 wt% on carbon black Johnson Matthey, HiSPEC 3000 was purchased from Alfa Aesar. A gas diffusion layer (GDL) Elat LT1400W single sided was purchased from NuVant Systems Inc. A
Naflon membrane NRE212 was purchased from Ion Power and nitrogen and oxygen gases were supplied in cylinders by PRAXAIR with 99.999% purity. All aqueous solutions were prepared using ultrapure water obtained from a Millipore Milli-Q system with resistivity >18 mn cm-1.
Synthesis of the Ti305M0o.2Sio.4 (TOMS) support structure
(H24Mo7N6024.4H20) was added to the solution. The pH of the solution was held constant at pH = 9 by adding NH4OH. The solution was continuously stirred at room temperature for another 5 h under N2 purging, and dried at 80 C. The obtained powder was annealed at 850 C
(heating rate of 10 C min-1) for 8 h under a reducing atmosphere (H2 : N2 10 : 90 vol%). The obtained Ti305Mo0.2 powder dispersed in a solution of (50: 50 vol%) ultrapure water and ethanol followed by the addition of 2 wt% Pluronic P123 surfactant and 10 wt%
Si NPs.
The solution was stirred at room temperature for another 3 h under N2 purging, and dried at 80 C. The obtained powder was annealed at 550 C (heating rate of 10 C min-1) for 5 h under a reducing atmosphere (H2: N2 10 : 90 vol%).
Synthesis of a Pt/Ti305Moo.2Sio.4 (Pt/TOMS) support
The obtained solution was filtered, washed with ultrapure water, and subsequently dried at 80 C under N2 purging. The obtained sample of Pt/TOMS was annealed at 450 C
(heating rate of 5 C m1n-1) for 4 h under a reducing atmosphere (H2: N2 10 :
90 vol%).
Physical characterization of the electrocatalysts
0.15418 nm) operating at 40 kV and 44 mA. Diffuse reflectance UV-vis spectra of TiO2(1V) oxide, anatase and synthesized TOMS were recorded using a Perkin Elmer Lambda-750S
UV/VIS spectrometer. The optical absorption spectra were used to determine the band gap of each sample by applying the Tauc equation. The surface composition of the Pt/TOMS catalyst was studied by XPS, employing the Thermo Scientific K-Alpha Angle-Resolved system equipped with a monochromatic Al Ka (1486.7 eV) X-ray source and a 180 double focusing hemispherical analyzer with a 128 channel detector with effective charge compensation. Transmission electron microscopy (TEM) images of the TOMS
support structure and the Pt/TOMS electrocatalyst were acquired using a Zeiss Libra 200MC Transmission Electron Microscopy (TEM) system operating at 200 kV.
Scanning Electron Microscopy (SEM) images were obtained using a Hitachi FlexSEM 1000 system equipped with an energy dispersive X-ray analyzer. The electrical conductivity of the TOMS support structure was measured in the solid state phase via two-point probe measurements. The TOMS powder was pelletized under a manual press (15000 pounds), resulting in the TOMS pellet with a diameter of 10 mm and a thickness of 1 mm.
The TOMS pellet was placed between two copper probes with 9.3 mm cross section, and then the potential in the range of 0.1-1.2 V vs. RHE was applied in order to measure the produced current.
Electrochemical characterization of the electrocatalysts
Impedance spectra were collected over a frequency range of 100 kHz to 0.1 Hz at a DC
bias potential of 0.425 V vs. RHE. The ORR activity was assessed using linear sweep voltammetry using a rotating disk electrode in 02-saturated solution. Catalyst durability was assessed using an accelerated stress test (AST) that involved repeated cycling of the working electrode potential between 0.05 and 1.25 V vs. RHE at a scan rate of 50 mV s-1, in an N2-saturated 0.5 M H2504 solution. According to the United States Department of Energy testing protocols, this potential range assures the accelerated corrosion of the support as well as the sintering of Pt NPs. The electrode condition was monitored by periodic CV
and EIS assessments throughout the AST. In addition, the ORR activity of each electrocatalyst was assessed before and after the AST.
Membrane electrode assembly (MEA) preparation and testing
While the applicant's teachings described herein are in conjunction with various embodiments for illustrative purposes, it is not intended that the applicant's teachings be limited to such embodiments as the embodiments described herein are intended to be examples. On the contrary, the applicant's teachings described and illustrated herein encompass various alternatives, modifications, and equivalents, without departing from the embodiments described herein, the general scope of which is defined in the appended claims.
Claims (20)
a support structure including:
at least one titanium suboxide;
a first dopant; and a second dopant; and a metal catalyst deposited on the support structure;
wherein the first dopant is a metal and the second dopant is a Group IV
element.
at least one titanium suboxide;
a first dopant; and a second dopant;
wherein the first dopant is a metal and the second dopant is Group IV element.
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| CA3019718A CA3019718A1 (en) | 2018-10-03 | 2018-10-03 | Fuel cell catalyst support based on doped titanium suboxides |
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Cited By (1)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN115744814A (en) * | 2022-09-28 | 2023-03-07 | 重庆大学 | Gamma-MoC/VN restricted domain catalyzed MgH2 nano composite hydrogen storage material and preparation method thereof |
-
2018
- 2018-10-03 CA CA3019718A patent/CA3019718A1/en active Pending
Cited By (2)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN115744814A (en) * | 2022-09-28 | 2023-03-07 | 重庆大学 | Gamma-MoC/VN restricted domain catalyzed MgH2 nano composite hydrogen storage material and preparation method thereof |
| CN115744814B (en) * | 2022-09-28 | 2024-05-10 | 重庆大学 | Gamma-MoC/VN (gamma-MoC/VN) domain-limited catalysis MgH2 nano composite hydrogen storage material and preparation method thereof |
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