Hongming Wang scite author profile

Development of efficient and robust electrocatalysts is critical for practical fuel cells. We report one-dimensional bunched platinum-nickel (Pt-Ni) alloy nanocages with a Pt-skin structure for the oxygen reduction reaction that display high mass activity (3.52 amperes per milligram platinum) and specific activity (5.16 milliamperes per square centimeter platinum), or nearly 17 and 14 times higher as compared with a commercial platinum on carbon (Pt/C) catalyst. The catalyst exhibits high stability with negligible activity decay after 50,000 cycles. Both the experimental results and theoretical calculations reveal the existence of fewer strongly bonded platinum-oxygen (Pt-O) sites induced by the strain and ligand effects. Moreover, the fuel cell assembled by this catalyst delivers a current density of 1.5 amperes per square centimeter at 0.6 volts and can operate steadily for at least 180 hours.

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Bismuth Oxides with Enhanced Bismuth–Oxygen Structure for Efficient Electrochemical Reduction of Carbon Dioxide to Formate

Deng

et al. 2019

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Electrochemical conversion of carbon dioxide (CO 2 ) into high-value chemical products has become a dramatic research area because of the efficient exploitation of carbon resources and simultaneous reduction of atmospheric CO 2 concentration. Herein, we report the bismuth-based catalyst in the efficient electroconversion of CO 2 for the formation of formate with a maximum Faradaic efficiency of 91% and partial current density of ∼8 mA cm −2 at −0.9 V vs RHE. Experimental and theoretical results show that the bismuth−oxygen structure of bismuth oxides is beneficial for a higher adsorption of CO 2 and the ratedetermining route switching from the initial fast pre-equilibrium of electron transfer process to the subsequent hydrogenation step, accompanied by a lower free energy of intermediate. This work may offer valuable insights into crystal structure engineering to achieve efficient electrocatalysts for selective CO 2 reduction toward generation of valuable products.

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Energy-saving hydrogen production coupling urea oxidation over a bifunctional nickel-molybdenum nanotube array

et al. 2019

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An Earth‐Abundant Catalyst‐Based Seawater Photoelectrolysis System with 17.9% Solar‐to‐Hydrogen Efficiency

et al. 2018

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The implementation of water splitting systems, powered by sustainable energy resources, appears to be an attractive strategy for producing high-purity H in the absence of the release of carbon dioxide (CO ). However, the high cost, impractical operating conditions, and unsatisfactory efficiency and stability of conventional methods restrain their large-scale development. Seawater covers 70% of the Earth's surface and is one of the most abundant natural resources on the planet. New research is looking into the possibility of using seawater to produce hydrogen through electrolysis and will provide remarkable insight into sustainable H production, if successful. Here, guided by density functional theory (DFT) calculations to predict the selectivity of gas-evolving catalysts, a seawater-splitting device equipped with affordable state-of-the-art electrocatalysts composed of earth-abundant elements (Fe, Co, Ni, and Mo) is demonstrated. This device shows excellent durability and specific selectivity toward the oxygen evolution reaction in seawater with near 100% Faradaic efficiency for the production of H and O . Powered by a single commercial III-V triple-junction photovoltaic cell, the integrated system achieves spontaneous and efficient generation of high-purity H and O from seawater at neutral pH with a remarkable 17.9% solar-to-hydrogen efficiency.

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Anodic Hydrazine Oxidation Assists Energy‐Efficient Hydrogen Evolution over a Bifunctional Cobalt Perselenide Nanosheet Electrode

et al. 2018

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Water electrolysis is a promising source of hydrogen; however, technological challenges remain. Intensive efforts have focused on developing highly efficient and earth-abundant electrocatalysts for water splitting. An effective strategy is proposed, using a bifunctional tubular cobalt perselenide nanosheet electrode, in which the sluggish oxygen evolution reaction is substituted with anodic hydrazine oxidation so as to assist energy-efficient hydrogen production. Specifically, this electrode produces a current density of 10 mA cm at -84 mV for hydrogen evolution and -17 mV for hydrazine oxidation in 1.0 m KOH and 0.5 m hydrazine electrolyte. An ultralow cell voltage of only 164 mV is required to generate a current density of 10 mA cm for 14 hours of stable water electrolysis.

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Hongming Wang

Engineering bunched Pt-Ni alloy nanocages for efficient oxygen reduction in practical fuel cells

Bismuth Oxides with Enhanced Bismuth–Oxygen Structure for Efficient Electrochemical Reduction of Carbon Dioxide to Formate

Energy-saving hydrogen production coupling urea oxidation over a bifunctional nickel-molybdenum nanotube array

An Earth‐Abundant Catalyst‐Based Seawater Photoelectrolysis System with 17.9% Solar‐to‐Hydrogen Efficiency

Anodic Hydrazine Oxidation Assists Energy‐Efficient Hydrogen Evolution over a Bifunctional Cobalt Perselenide Nanosheet Electrode

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