Siyu Yao scite author profile

Polymer electrolyte membrane fuel cells (PEMFCs) running on hydrogen are attractive alternative power supplies for a range of applications, with in situ release of the required hydrogen from a stable liquid offering one way of ensuring its safe storage and transportation before use. The use of methanol is particularly interesting in this regard, because it is inexpensive and can reform itself with water to release hydrogen with a high gravimetric density of 18.8 per cent by weight. But traditional reforming of methanol steam operates at relatively high temperatures (200-350 degrees Celsius), so the focus for vehicle and portable PEMFC applications has been on aqueous-phase reforming of methanol (APRM). This method requires less energy, and the simpler and more compact device design allows direct integration into PEMFC stacks. There remains, however, the need for an efficient APRM catalyst. Here we report that platinum (Pt) atomically dispersed on α-molybdenum carbide (α-MoC) enables low-temperature (150-190 degrees Celsius), base-free hydrogen production through APRM, with an average turnover frequency reaching 18,046 moles of hydrogen per mole of platinum per hour. We attribute this exceptional hydrogen production-which far exceeds that of previously reported low-temperature APRM catalysts-to the outstanding ability of α-MoC to induce water dissociation, and to the fact that platinum and α-MoC act in synergy to activate methanol and then to reform it.

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Atomic-layered Au clusters on α-MoC as catalysts for the low-temperature water-gas shift reaction

Yao

Zhang

Zhou

et al. 2017

Science

555

500

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The water-gas shift (WGS) reaction (where carbon monoxide plus water yields dihydrogen and carbon dioxide) is an essential process for hydrogen generation and carbon monoxide removal in various energy-related chemical operations. This equilibrium-limited reaction is favored at a low working temperature. Potential application in fuel cells also requires a WGS catalyst to be highly active, stable, and energy-efficient and to match the working temperature of on-site hydrogen generation and consumption units. We synthesized layered gold (Au) clusters on a molybdenum carbide (α-MoC) substrate to create an interfacial catalyst system for the ultralow-temperature WGS reaction. Water was activated over α-MoC at 303 kelvin, whereas carbon monoxide adsorbed on adjacent Au sites was apt to react with surface hydroxyl groups formed from water splitting, leading to a high WGS activity at low temperatures.

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Highly selective oxidation of methane to methanol at ambient conditions by titanium dioxide-supported iron species

et al. 2018

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Methane activation at moderate conditions and with good selectivity for value-added chemicals still remains a huge challenge. Here, we present a highly selective catalyst for the transformation of methane to methanol composed of highly dispersed iron species on TiO2. The catalyst operates under moderate light irradiation (close to one sun) and at ambient conditions. The optimised sample shows a 15% conversion rate for CH4 with an alcohol selectivity of over 97% (methanol selectivity over 90%) and a yield of 18 moles of alcohol per mole of iron active site in just three hours. XPS measurements with and without Xenon lamp irradiation, light intensity-modulated spectroscopies, photoelectrochemical measurements, XANES and EXAFS spectra, as well as isotopic analysis confirm the function of the major ironcontaining species, namely FeOOH and Fe2O3, which enhance charge transfer and separation, decrease the overpotential of the reduction reaction and improves selectivity towards methanol over CO2 production.

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Electrochemical reduction of CO₂to synthesis gas with controlled CO/H₂ratios

Sheng

Kattel

Yao

et al. 2017

Energy Environ. Sci.

351

337

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Hierarchically Porous M–N–C (M = Co and Fe) Single‐Atom Electrocatalysts with Robust MN_x Active Moieties Enable Enhanced ORR Performance

Zhu

Shi

et al. 2018

Advanced Energy Materials

560

324

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The great interest in fuel cells inspires a substantial amount of research on nonprecious metal catalysts as alternatives to Pt-based oxygen reduction reaction (ORR) electrocatalysts. In this work, bimodal template-based synthesis strategies are proposed for the scalable preparation of hierarchically porous M-N-C (M = Fe or Co) single-atom electrocatalysts featured with active and robust MN 2 active moieties. Multiscale tuning of M-N-C catalysts regarding increasing the number of active sites and boosting the intrinsic activity of each active site is realized simultaneously at a singleatom scale. In addition to the antipoisoning power and high affinity for O 2 , the optimized Fe-N-C catalysts with FeN 2 active site presents a superior electrocatalytic activity for ORR with a half-wave potential of 0.927 V (vs reversible hydrogen electrode (RHE)) in an alkaline medium, which is 49 and 55 mV higher than those of the Co-N-C counterpart and commercial Pt/C, respectively. Density functional theory calculations reveal that the FeN 2 site is more active than the CoN 2 site for ORR due to the lower energy barriers of the intermediates and products involved. The present work may help rational design of more robust ORR electrocatalysts at the atomic level, realizing the significant advances in electrochemical conversion and storage devices. Single-Atom ElectrocatalystsThe ORCID identification number(s) for the author(s) of this article can be found under https://doi.

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Tuning the Selectivity of Catalytic Carbon Dioxide Hydrogenation over Iridium/Cerium Oxide Catalysts with a Strong Metal–Support Interaction

et al. 2017

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A one-step ligand-free method based on an adsorption-precipitation process was developed to fabricate iridium/cerium oxide (Ir/CeO ) nanocatalysts. Ir species demonstrated a strong metal-support interaction (SMSI) with the CeO substrate. The chemical state of Ir could be finely tuned by altering the loading of the metal. In the carbon dioxide (CO ) hydrogenation reaction it was shown that the chemical state of Ir species-induced by a SMSI-has a major impact on the reaction selectivity. Direct evidence is provided indicating that a single-site catalyst is not a prerequisite for inhibition of methanation and sole production of carbon monoxide (CO) in CO hydrogenation. Instead, modulation of the chemical state of metal species by a strong metal-support interaction is more important for regulation of the observed selectivity (metallic Ir particles select for methane while partially oxidized Ir species select for CO production). The study provides insight into heterogeneous catalysts at nano, sub-nano, and atomic scales.

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Stable and Efficient Single-Atom Zn Catalyst for CO₂ Reduction to CH₄

et al. 2020

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The development of highly active and durable catalysts for electrochemical reduction of CO2 (ERC) to CH4 in aqueous media is an efficient and environmentally friendly solution to address global problems in energy and sustainability. In this work, an electrocatalyst consisting of single Zn atoms supported on microporous N-doped carbon was designed to enable multielectron transfer for catalyzing ERC to CH4 in 1 M KHCO3 solution. This catalyst exhibits a high Faradaic efficiency (FE) of 85%, a partial current density of −31.8 mA cm–2 at a potential of −1.8 V versus saturated calomel electrode, and remarkable stability, with neither an obvious current drop nor large FE fluctuation observed during 35 h of ERC, indicating a far superior performance than that of dominant Cu-based catalysts for ERC to CH4. Theoretical calculations reveal that single Zn atoms largely block CO generation and instead facilitate the production of CH4.

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A stable low-temperature H2-production catalyst by crowding Pt on α-MoC

Zhang

Deng

et al. 2021

Nature

303

252

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Siyu Yao

Low-temperature hydrogen production from water and methanol using Pt/α-MoC catalysts

Atomic-layered Au clusters on α-MoC as catalysts for the low-temperature water-gas shift reaction

Highly selective oxidation of methane to methanol at ambient conditions by titanium dioxide-supported iron species

Electrochemical reduction of CO₂to synthesis gas with controlled CO/H₂ratios

Hierarchically Porous M–N–C (M = Co and Fe) Single‐Atom Electrocatalysts with Robust MN_x Active Moieties Enable Enhanced ORR Performance

Tuning the Selectivity of Catalytic Carbon Dioxide Hydrogenation over Iridium/Cerium Oxide Catalysts with a Strong Metal–Support Interaction

Stable and Efficient Single-Atom Zn Catalyst for CO₂ Reduction to CH₄

A stable low-temperature H2-production catalyst by crowding Pt on α-MoC

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Siyu Yao

Low-temperature hydrogen production from water and methanol using Pt/α-MoC catalysts

Atomic-layered Au clusters on α-MoC as catalysts for the low-temperature water-gas shift reaction

Highly selective oxidation of methane to methanol at ambient conditions by titanium dioxide-supported iron species

Electrochemical reduction of CO2to synthesis gas with controlled CO/H2ratios

Hierarchically Porous M–N–C (M = Co and Fe) Single‐Atom Electrocatalysts with Robust MNx Active Moieties Enable Enhanced ORR Performance

Tuning the Selectivity of Catalytic Carbon Dioxide Hydrogenation over Iridium/Cerium Oxide Catalysts with a Strong Metal–Support Interaction

Stable and Efficient Single-Atom Zn Catalyst for CO2 Reduction to CH4

A stable low-temperature H2-production catalyst by crowding Pt on α-MoC

Contact Info

Product

Resources

About

Electrochemical reduction of CO₂to synthesis gas with controlled CO/H₂ratios

Hierarchically Porous M–N–C (M = Co and Fe) Single‐Atom Electrocatalysts with Robust MN_x Active Moieties Enable Enhanced ORR Performance

Stable and Efficient Single-Atom Zn Catalyst for CO₂ Reduction to CH₄