Cu-based high-entropy two-dimensional oxide as stable and active photothermal catalyst

[1]  Yaguang Li,et al.  Nanostructured Materials for Photothermal Carbon Dioxide Hydrogenation: Regulating Solar Utilization and Catalytic Performance. , 2023, ACS nano.

[2]  Yaguang Li,et al.  Low Temperature Thermal and Solar Heating Carbon‐Free Hydrogen Production from Ammonia Using Nickel Single Atom Catalysts , 2022, Advanced Energy Materials.

[3]  Sicong Ma,et al.  The role of Cu1–O3 species in single-atom Cu/ZrO2 catalyst for CO2 hydrogenation , 2022, Nature Catalysis.

[4]  Todd J. Toops,et al.  Defect Engineering of Ceria Nanocrystals for Enhanced Catalysis via a High-Entropy Oxide Strategy , 2022, ACS central science.

[5]  V. Sglavo,et al.  Ultra-fast high-temperature sintering (UHS) of Ce0.2Zr0.2Y0.2Gd0.2La0.2O2−δ fluorite-structured entropy-stabilized oxide (F-ESO) , 2022, Scripta Materialia.

[6]  M. White,et al.  Allylic C–H amination cross-coupling furnishes tertiary amines by electrophilic metal catalysis , 2022, Science.

[7]  Guo‐Cong Guo,et al.  Ambient-pressure synthesis of ethylene glycol catalyzed by C60-buffered Cu/SiO2 , 2022, Science.

[8]  E. Doris,et al.  Fullerenes make copper catalysis better , 2022, Science.

[9]  M. Chi,et al.  Ultrasound-mediated synthesis of nanoporous fluorite-structured high-entropy oxides toward noble metal stabilization , 2022, iScience.

[10]  F. Ritort,et al.  Molten globule–like transition state of protein barnase measured with calorimetric force spectroscopy , 2022, Proceedings of the National Academy of Sciences of the United States of America.

[11]  F. Zaera Designing Sites in Heterogeneous Catalysis: Are We Reaching Selectivities Competitive With Those of Homogeneous Catalysts? , 2022, Chemical reviews.

[12]  T. Shin,et al.  Abrading bulk metal into single atoms , 2022, Nature Nanotechnology.

[13]  Feng Zhang,et al.  General heterostructure strategy of photothermal materials for scalable solar-heating hydrogen production without the consumption of artificial energy , 2022, Nature Communications.

[14]  G. Ozin,et al.  Stable Cu Catalysts Supported by Two‐dimensional SiO2 with Strong Metal–Support Interaction , 2022, Advanced science.

[15]  Fuzhen Xuan,et al.  Induced activation of the commercial Cu/ZnO/Al2O3 catalyst for the steam reforming of methanol , 2022, Nature Catalysis.

[16]  H. Hahn,et al.  Determining role of individual cations in high entropy oxides: Structure and reversible tuning of optical properties , 2022, Scripta Materialia.

[17]  Jinhua Ye,et al.  Cooperative catalysis coupling photo-/photothermal effect to drive Sabatier reaction with unprecedented conversion and selectivity , 2021, Joule.

[18]  K. Page,et al.  Persistent Structure and Frustrated Magnetism in High Entropy Rare-Earth Zirconates. , 2021, Small.

[19]  Pengfei Zhang,et al.  Enthalpy-change driven synthesis of high-entropy perovskite nanoparticles , 2021, Nano Research.

[20]  Jihong Yu,et al.  Emerging applications of zeolites in catalysis, separation and host–guest assembly , 2021, Nature Reviews Materials.

[21]  G. Ozin,et al.  Greenhouse-inspired supra-photothermal CO2 catalysis , 2021, Nature Energy.

[22]  D. Leigh,et al.  A catalysis-driven artificial molecular pump , 2021, Nature.

[23]  Liangbing Wang,et al.  Copper‐Based Plasmonic Catalysis: Recent Advances and Future Perspectives , 2021, Advanced materials.

[24]  Lili Lin,et al.  Reversing sintering effect of Ni particles on γ-Mo2N via strong metal support interaction , 2021, Nature Communications.

[25]  Haotian Wang,et al.  Converting CO2 to liquid fuel on MoS2 vacancies , 2021 .

[26]  Bastian Reiprich,et al.  Effect of zeolite topology on NH3-SCR activity and stability of Cu-exchanged zeolites , 2021 .

[27]  S. Dai,et al.  High-entropy materials for catalysis: A new frontier , 2021, Science Advances.

[28]  Peijie Ma,et al.  Atomically dispersed Pt/CeO2 catalyst with superior CO selectivity in reverse water gas shift reaction , 2021 .

[29]  Pengxiang Qiu,et al.  Modification of graphitic carbon nitride by elemental boron cocatalyst with high-efficient charge transfer and photothermal conversion , 2021 .

[30]  Zili Wu,et al.  Vacancy engineering of the nickel-based catalysts for enhanced CO2 methanation , 2021 .

[31]  S. Pennycook,et al.  High-entropy-stabilized chalcogenides with high thermoelectric performance , 2021, Science.

[32]  Jin Zhang,et al.  Growth of Homogeneous High-density Horizontal SWNT Arrays on Sapphire via a Magnesium-assisted Catalyst Anchoring Strategy. , 2021, Angewandte Chemie.

[33]  Jongwoo Lim,et al.  Formation of FeOOH Nanosheets Induces Substitutional Doping of CeO2−x with High‐Valence Ni for Efficient Water Oxidation , 2020, Advanced Energy Materials.

[34]  M. Nishijima,et al.  Development of CO2-to-Methanol Hydrogenation Catalyst by Focusing on the Coordination Structure of the Cu Species in Spinel-Type Oxide Mg1–xCuxAl2O4 , 2020 .

[35]  F. Cárdenas-Lizana,et al.  Phenylacetylene hydrogenation coupled with benzyl alcohol dehydrogenation over Cu/CeO2: A consideration of Cu oxidation state , 2020, Journal of Catalysis.

[36]  Yadong Li,et al.  Electronic Metal–Support Interaction of Single‐Atom Catalysts and Applications in Electrocatalysis , 2020, Advanced materials.

[37]  R. Cioffi,et al.  A Simple and Effective Predictor to Design Novel Fluorite-Structured High Entropy Oxides (HEOs) , 2020, Acta Materialia.

[38]  Yaguang Li,et al.  Outdoor sunlight-driven scalable water-gas shift reaction through novel photothermal device-supported CuOx/ZnO/Al2O3 nanosheets with a hydrogen generation rate of 192 mmol g−1 h−1 , 2020 .

[39]  B. Iversen,et al.  Autocatalytic Formation of High‐Entropy Alloy Nanoparticles , 2020, Angewandte Chemie.

[40]  H. Tan,et al.  Highly efficient and robust Cu catalyst for non-oxidative dehydrogenation of ethanol to acetaldehyde and hydrogen , 2020 .

[41]  Paul N. Duchesne,et al.  Bismuth atom tailoring of indium oxide surface frustrated Lewis pairs boosts heterogeneous CO2 photocatalytic hydrogenation , 2020, Nature Communications.

[42]  M. Muhler,et al.  Identifying the nature of the active sites in methanol synthesis over Cu/ZnO/Al2O3 catalysts , 2020, Nature Communications.

[43]  C. Ospina,et al.  Determining the Surface Atomic Population of CuxNi1–x/CeO2 (0 < x ≤ 1) Nanoparticles during the Reverse Water–Gas Shift (RWGS) Reaction , 2020 .

[44]  N. Nelson,et al.  In Situ Dispersion of Pd on TiO2 During Reverse Water-Gas Shift Reaction: Formation of Atomically Dispersed Pd. , 2020, Angewandte Chemie.

[45]  Yaguang Li,et al.  Realizing efficient natural sunlight-driven photothermal selective catalytic reduction of nitrogen oxides by AlNx assisted W doped Fe2O3 nanosheets , 2020 .

[46]  L. Deng,et al.  Supported mesoporous Cu/CeO2-δ catalyst for CO2 reverse water–gas shift reaction to syngas , 2020 .

[47]  T. Reina,et al.  CO2 valorisation via reverse water-gas shift reaction using promoted Fe/CeO2-Al2O3 catalysts: Showcasing the potential of advanced catalysts to explore new processes design , 2020 .

[48]  Jianhong Liu,et al.  Carbon dioxide electroreduction on single-atom nickel decorated carbon membranes with industry compatible current densities , 2020, Nature Communications.

[49]  K. Butler,et al.  CO2 Photoreduction: Heterostructure Engineering of a Reverse Water Gas Shift Photocatalyst (Adv. Sci. 22/2019) , 2019, Advanced Science.

[50]  Yonggang Yao,et al.  Highly efficient decomposition of ammonia using high-entropy alloy catalysts , 2019, Nature Communications.

[51]  Jinhua Ye,et al.  Selective light absorber-assisted single nickel atom catalysts for ambient sunlight-driven CO2 methanation , 2019, Nature Communications.

[52]  T. Hayat,et al.  Decontamination of U(VI) on graphene oxide/Al2O3 composites investigated by XRD, FT-IR and XPS techniques. , 2019, Environmental pollution.

[53]  S. Sengupta,et al.  Catalytic performance of Co and Ni doped Fe-based catalysts for the hydrogenation of CO2 to CO via reverse water-gas shift reaction , 2019, Journal of Environmental Chemical Engineering.

[54]  C. V. Singh,et al.  Catalytic CO2 reduction by palladium-decorated silicon–hydride nanosheets , 2018, Nature Catalysis.

[55]  P. Ajayan,et al.  Emerging Carbon‐Based Heterogeneous Catalysts for Electrochemical Reduction of Carbon Dioxide into Value‐Added Chemicals , 2018, Advanced materials.

[56]  Feiyan Hao,et al.  Assembling Ultrasmall Copper‐Doped Ruthenium Oxide Nanocrystals into Hollow Porous Polyhedra: Highly Robust Electrocatalysts for Oxygen Evolution in Acidic Media , 2018, Advanced materials.

[57]  Steven D. Lacey,et al.  Carbothermal shock synthesis of high-entropy-alloy nanoparticles , 2018, Science.

[58]  Paul N. Duchesne,et al.  Tailoring Surface Frustrated Lewis Pairs of In2O3− x(OH)y for Gas‐Phase Heterogeneous Photocatalytic Reduction of CO2 by Isomorphous Substitution of In3+ with Bi3+ , 2018, Advanced science.

[59]  Yijie Huo,et al.  Solar water splitting by photovoltaic-electrolysis with a solar-to-hydrogen efficiency over 30% , 2016, Nature Communications.

[60]  S. Pennycook,et al.  Visible and Near‐Infrared Photothermal Catalyzed Hydrogenation of Gaseous CO2 over Nanostructured Pd@Nb2O5 , 2016, Advanced science.

[61]  G. Ozin,et al.  Spatial Separation of Charge Carriers in In2O3-x(OH)y Nanocrystal Superstructures for Enhanced Gas-Phase Photocatalytic Activity. , 2016, ACS nano.

[62]  Li-ping Zhu,et al.  Enhancing photocatalytic activity for visible-light-driven H2 generation with the surface reconstructed LaTiO2N nanostructures , 2015 .

[63]  Hengyong Xu,et al.  Characterizations and activities of the nano-sized Ni/Al2O3 and Ni/La-Al2O3 catalysts for NH3 decomposition , 2005 .

[64]  Yong Wang,et al.  Sorption-enhanced synthetic natural gas (SNG) production from syngas: A novel process combining CO methanation, water-gas shift, and CO2 capture , 2014 .