10 research outputs found

    Simultaneous Operando Time-Resolved XAFSā€“XRD Measurements of a Pt/C Cathode Catalyst in Polymer Electrolyte Fuel Cell under Transient Potential Operations

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    We have succeeded in simultaneous <i>operando</i> time-resolved quick X-ray absorption fine structure (QXAFS)ā€“X-ray diffraction (XRD) measurements at each acquisition time of 20 ms for a Pt/C cathode catalyst in a polymer electrolyte fuel cell (PEFC), while measuring the current/charge of the PEFC during the transient voltage cyclic processes (0.4 V<sub>RHE</sub> ā†’ 1.4 V<sub>RHE</sub> ā†’ 0.4 V<sub>RHE</sub>) under H<sub>2</sub>(anode)ā€“N<sub>2</sub>(cathode). The rate constants for Ptā€“O bond formation/dissociation, Pt charging/discharging, Ptā€“Pt bond dissociation/reformation, and decrease/increase of Pt metallic-phase core size under the transient potential operations were determined by the combined time-resolved QXAFSā€“XRD technique. The present study provides a new insight into the transient-response reaction mechanism and structural transformation in the Pt surface layer and bulk, which are relevant to the origin of PEFC activity and durability as key issues for the development of next-generation PEFCs

    The Relationship between the Active Pt Fraction in a PEFC Pt/C Catalyst and the ECSA and Mass Activity during Start-Up/Shut-Down Degradation by in Situ Time-Resolved XAFS Technique

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    Transient-response kinetics of the transformations (six elementary steps) of the Pt valence, coordination number of Ptā€“Pt bonds, and coordination number of Ptā€“O bonds of a Pt/C cathode catalyst in a polymer electrolyte fuel cell (PEFC) under cyclic voltage operations (0.4 ā†’ 1.4 ā†’ 0.4 <i>V</i><sub>RHE</sub>) during anodeā€“gas exchange (AGEX) treatments (start-up/shut-down) has been studied by in situ time-resolved quick X-ray absorption fine structure (QXAFS, 100 ms/spectrum). The transient-response analysis identified the existence and fractions of three different kinds (active, less active, and inactive) of Pt nanoparticles in the Pt/C cathode. The active Pt nanoparticles degraded to less active and inactive Pt nanoparticles by the AGEX cycles. The degradation probability and mechanism were clarified by the transient-response kinetics. The electrochemical surface area (ECSA) and mass activity (MA) of the Pt/C cathode catalyst also decreased with increasing AGEX cycles. It was found that the change in the sum of the fractions of the active and less active Pt nanoparticles correlates with the change in the ECSA and MA during the AGEX treatments. The in situ time-resolved QXAFS analysis provides direct information on the dynamic behavior of the Pt/C catalyst relevant to the electrochemical performance and property under the operando conditions for thorough understanding of the degradation process toward PEFC improvement

    Rate Enhancements in Structural Transformations of Ptā€“Co and Ptā€“Ni Bimetallic Cathode Catalysts in Polymer Electrolyte Fuel Cells Studied by in Situ Time-Resolved Xā€‘ray Absorption Fine Structure

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    In situ time-resolved X-ray absorption fine structure spectra of Pt/C, Pt<sub>3</sub>Co/C, and Pt<sub>3</sub>Ni/C cathode electrocatalysts in membrane electrode assemblies (catalyst loading: 0.5 mg<sub>metal</sub> cm<sup>ā€“2</sup>) were successfully measured every 100 ms for a voltage cycling process between 0.4 and 1.0 V. Systematic analysis of in situ time-resolved X-ray absorption near-edge structure and extended X-ray absorption fine structure spectra in the molecular scale revealed the structural kinetics of the Pt and Pt<sub>3</sub>M (M = Co, Ni) bimetallic cathode catalysts under polymer electrolyte fuel cell operating conditions, and the rate constants of Pt charging, Ptā€“O bond formation/breaking, and Ptā€“Pt bond breaking/re-formation relevant to the fuel cell performances were successfully determined. The addition of the 3d transition metals to Pt reduced the Pt oxidation state and significantly enhanced the reaction rates of Pt discharging, Ptā€“O bond breaking, and Ptā€“Pt bond re-forming in the reductive process from 1.0 to 0.4 V

    Kinetics and Mechanism of Redox Processes of Pt/C and Pt<sub>3</sub>Co/C Cathode Electrocatalysts in a Polymer Electrolyte Fuel Cell during an Accelerated Durability Test

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    The degradation of Pt electrocatalysts in membrane electrode assemblies (MEAs) of polymer electrolyte fuel cells under working conditions is a serious problem for their practical use. Here we report the kinetics and mechanism of redox reactions at the surfaces of Pt/C and Pt<sub>3</sub>Co/C cathode electrocatalysts during catalyst degradation processes by an accelerated durability test (ADT) studied by operando time-resolved X-ray absorption fine structure (XAFS) spectroscopy. Systematic analysis of a series of Pt L<sub>III</sub>-edge time-resolved XAFS spectra measured every 100 ms at different degradation stages revealed changes in the kinetics of Pt redox reactions on Pt/C and Pt<sub>3</sub>Co/C cathode electrocatalysts. In the case of Pt/C, as the number of ADT cycles increased, structural changes for Pt redox reactions (charging, surface, and subsurface oxidation) became less sensitive because of the agglomeration of catalyst particles. It was found that their rate constants were almost constant independent of the agglomeration of the Pt electrocatalyst. On the other hand, in the case of Pt<sub>3</sub>Co/C, the rate constants of the redox reactions of the cathode electrocatalyst gradually reduced as the number of ADT cycles increased. The differences in the kinetics for the redox processes would be differences in the degradation mechanism of these cathode electrocatalysts

    Simultaneous Improvements in Performance and Durability of an Octahedral PtNi<sub><i>x</i></sub>/C Electrocatalyst for Next-Generation Fuel Cells by Continuous, Compressive, and Concave Pt Skin Layers

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    Simultaneous improvements in oxygen reduction reaction (ORR) activity and long-term durability of Pt-based cathode catalysts are indispensable for the development of next-generation polymer electrolyte fuel cells but are still a major dilemma. We present a robust octahedral coreā€“shell PtNi<sub><i>x</i></sub>/C electrocatalyst with high ORR performance (mass activity and surface specific activity 6.8ā€“16.9 and 20.3ā€“24.0 times larger than those of Pt/C, respectively) and durability (negligible loss after 10000 accelerated durability test (ADT) cycles). The key factors of the robust octahedral nanostructure (coreā€“shell Pt<sub>73</sub>Ni<sub>27</sub>/C) responsible for the remarkable activity and durability were found to be three continuous Pt skin layers with 2.0ā€“3.6% compressive strain, concave facet arrangements (concave defects and high coordination), a symmetric Pt/Ni distribution, and a Pt<sub>67</sub>Ni<sub>33</sub> intermetallic core, as found by STEM-EDS, in situ XAFS, XPS, etc. The robust coreā€“shell Pt<sub>73</sub>Ni<sub>27</sub>/C was produced by the partial release of the stress, Pt/Ni rearrangement, and dimension reduction of an as-synthesized octahedral Pt<sub>50</sub>Ni<sub>50</sub>/C with 3.6ā€“6.7% compressive Pt skin layers by Ni leaching during the activation process. The present results on the tailored synthesis of the PtNi<sub><i>x</i></sub> structure and composition and the better control of the robust catalytic architecture renew the current knowledge and viewpoint for instability of octahedral PtNi<sub><i>x</i></sub>/C samples to provide a new insight into the development of next-generation PEFC cathode catalysts

    Same-View Nano-XAFS/STEM-EDS Imagings of Pt Chemical Species in Pt/C Cathode Catalyst Layers of a Polymer Electrolyte Fuel Cell

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    We have made the first success in the same-view imagings of 2D nano-XAFS and TEM/STEM-EDS under a humid N<sub>2</sub> atmosphere for Pt/C cathode catalyst layers in membrane electrode assemblies (MEAs) of polymer electrolyte fuel cells (PEFCs) with Nafion membrane to examine the degradation of Pt/C cathodes by anode gas exchange cycles (start-up/shut-down simulations of PEFC vehicles). The same-view imaging under the humid N<sub>2</sub> atmosphere provided unprecedented spatial information on the distribution of Pt nanoparticles and oxidation states in the Pt/C cathode catalyst layer as well as Nafion ionomer-filled nanoholes of carbon support in the wet MEA, which evidence the origin of the formation of Pt oxidation species and isolated Pt nanoparticles in the nanohole areas of the cathode layer with different Pt/ionomer ratios, relevant to the degradation of PEFC catalysts

    Surface-Regulated Nano-SnO<sub>2</sub>/Pt<sub>3</sub>Co/C Cathode Catalysts for Polymer Electrolyte Fuel Cells Fabricated by a Selective Electrochemical Sn Deposition Method

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    We have achieved significant improvements for the oxygen reduction reaction activity and durability with new SnO<sub>2</sub>-nanoislands/Pt<sub>3</sub>Co/C catalysts in 0.1 M HClO<sub>4</sub>, which were regulated by a strategic fabrication using a new selective electrochemical Sn deposition method. The nano-SnO<sub>2</sub>/Pt<sub>3</sub>Co/C catalysts with Pt/Sn = 4/1, 9/1, 11/1, and 15/1 were characterized by STEM-EDS, XRD, XRF, XPS, in situ XAFS, and electrochemical measurements to have a Pt<sub>3</sub>Co core/Pt skeleton-skin structure decorated with SnO<sub>2</sub> nanoislands at the compressive Pt surface with the defects and dislocations. The high performances of nano-SnO<sub>2</sub>/Pt<sub>3</sub>Co/C originate from efficient electronic modification of the Pt skin surface (site 1) by both the Co of the Pt<sub>3</sub>Co core and surface nano-SnO<sub>2</sub> and more from the unique property of the periphery sites of the SnO<sub>2</sub> nanoislands at the compressive Pt skeleton-skin surface (more active site 2), which were much more active than expected from the d-band center values. The white line peak intensity of the nano-SnO<sub>2</sub>/Pt<sub>3</sub>Co/C revealed no hysteresis in the potential upā€“down operations between 0.4 and 1.0 V versus RHE, unlike the cases of Pt/C and Pt<sub>3</sub>Co/C, resulting in the high ORR performance. Here we report development of a new class of cathode catalysts with two different active sites for next-generation polymer electrolyte fuel cells

    Key Structural Kinetics for Carbon Effects on the Performance and Durability of Pt/Carbon Cathode Catalysts in Polymer Electrolyte Fuel Cells Characterized by In Situ Time-Resolved Xā€‘ray Absorption Fine Structure

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    The structural kinetics (rate constants for electronic and structural transformations) of the Pt charging/discharging, Ptā€“Pt bond dissociation/re-formation, and Ptā€“O bond formation/dissociation of Pt/Ketjenblack, Pt/acetylene black, and Pt/multiwalled carbon nanotube cathode catalysts in polymer electrolyte fuel cell (PEFC) membrane electrode assemblies (MEAs) under transient potential operations (0.4 V<sub>RHE</sub> ā†’ 1.4 V<sub>RHE</sub> ā†’ 0.4 V<sub>RHE</sub>) has been studied by in situ/operando time-resolved quick X-ray absorption fine structure (QXAFS; 100 ms/spectrum), while measuring electrochemical currents/charges in the MEAs under the potential operations. From the systematic QXAFS analysis for potential-dependent surface structures and rate constants (<i>k</i> and <i>k</i>ā€²) for the transformations of Pt nanoparticles under the operations (0.4 V<sub>RHE</sub> ā†’ 1.4 V<sub>RHE</sub> and 1.4 V<sub>RHE</sub> ā†’ 0.4 V<sub>RHE</sub>), respectively, we have found the structural kinetics (<i>k</i>ā€²<sub>Ptā€“O</sub> and <i>k</i>ā€²<sub>valence</sub>) controlling the oxygen reduction reaction (ORR) activity and also the structural kinetics (<i>k</i>ā€²<sub>Ptā€“Pt</sub>/<i>k</i><sub>Ptā€“Pt</sub>) reflecting the durability of the cathode catalysts. The relaxation time of the Ptā€“Pt bond re-formation and Ptā€“O bond dissociation processes in the activated MEAs was also suggested to predict the relative durability of similar kinds of cathode catalysts. The in situ time-resolved XAFS analysis provided direct information on the key structural kinetics of the Pt/C catalysts themselves for thorough understanding of the cathode catalysis toward PEFC improvement

    Protracted Relaxation Dynamics of Lithium Heterogeneity in Solid-State Battery Electrodes

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    The lithium (Li) heterogeneity formed in the composite electrodes has a significant impact on the performance of solid-state batteries (SSBs). Whereas the influence of various factors on the Li heterogeneity, such as (dis)charge currents, ionic and/or electronic conductivity of the constituent materials, and interfacial charge transfer kinetics, is extensively studied, the influence of the relaxation on the Li heterogeneity in SSB electrodes is largely unexplored, despite its unignorable impact on the battery performance. Here, we performed a three-dimensional operando evaluation of the relaxation dynamics of the electrode-scale Li heterogeneity in a composite SSB electrode under open-circuit conditions after charging using the computed tomography combined with X-ray absorption near-edge structure spectroscopy (CT-XANES). In contrast to the electrode for the liquid-based Li-ion batteries, the Li heterogeneity formed in the composite SSB electrode during charging was not fully relaxed, even after a long open-circuit hold, leaving both higher and lower Li content regions. Such protracted relaxation dynamics in the composite SSB electrode may be due to the high interfacial resistance between active material particles as well as between active material and solid electrolyte particles and is potentially an essential issue for SSBs. This work demonstrated that our CT-XANES technique can three-dimensionally resolve the relaxation dynamics of Li heterogeneity within SSB electrodes, which has only been analyzed indirectly by conventional electrochemical methods such as electrochemical impedance spectroscopy. Our technique can be a valuable tool for identifying detrimental factors affecting the battery performance, ultimately contributing to the development of high-performance SSBs

    Operando Time-Resolved X-ray Absorption Fine Structure Study for Surface Events on a Pt<sub>3</sub>Co/C Cathode Catalyst in a Polymer Electrolyte Fuel Cell during Voltage-Operating Processes

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    The structural kinetics of surface events on a Pt<sub>3</sub>Co/C cathode catalyst in a polymer electrolyte fuel cell (PEFC) was investigated by operando time-resolved X-ray absorption fine structure (XAFS) with a time resolution of 500 ms. The rate constants of electrochemical reactions, the changes in charge density on Pt, and the changes in the local coordination structures of the Pt<sub>3</sub>Co alloy catalyst in the PEFC were successfully evaluated during fuel-cell voltage-operating processes. Significant time lags were observed between the electrochemical reactions and the structural changes in the Pt<sub>3</sub>Co alloy catalyst. The rate constants of all the surface events on the Pt<sub>3</sub>Co/C catalyst were significantly higher than those on the Pt/C catalyst, suggesting the advantageous behaviors (cell performance and catalyst durability) on the Pt<sub>3</sub>Co alloy cathode catalyst
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