Deciphering engineering principle of three-phase interface for advanced gas-involved electrochemical reactions

[1]  Mengfan Wang,et al.  Deciphering Electrolyte Selection for Electrochemical Reduction of Carbon Dioxide and Nitrogen to High‐Value‐Added Chemicals , 2023, Advanced Functional Materials.

[2]  Mengfan Wang,et al.  Covalent organic frameworks towards photocatalytic applications: Design principles, achievements, and opportunities , 2023, Coordination Chemistry Reviews.

[3]  Mengfan Wang,et al.  Turning Waste into Wealth: Sustainable Production of High-Value-Added Chemicals from Catalytic Coupling of Carbon Dioxide and Nitrogenous Small Molecules. , 2022, ACS nano.

[4]  X. Li,et al.  A hierarchically structured tin-cobalt composite with an enhanced electronic effect for high-performance CO2 electroreduction in a wide potential range , 2022, Journal of Energy Chemistry.

[5]  Mengfan Wang,et al.  Advancing the Electrochemistry of Gas‐Involved Reactions through Theoretical Calculations and Simulations from Microscopic to Macroscopic , 2022, Advanced Functional Materials.

[6]  Ke Chu,et al.  Selenium-vacancy-rich WSe2 for nitrate electroreduction to ammonia. , 2022, Journal of colloid and interface science.

[7]  Ke Chu,et al.  B-doped MoS2 for nitrate electroreduction to ammonia. , 2022, Journal of colloid and interface science.

[8]  Jiujun Zhang,et al.  Molybdenum disulfide (MoS2)–based electrocatalysts for hydrogen evolution reaction—from mechanism to manipulation , 2022, Journal of Energy Chemistry.

[9]  Xiaolin Zhao,et al.  High-Efficiency N2 Electroreduction Enabled by Se-Vacancy-Rich WSe2-x in Water-in-Salt Electrolytes. , 2022, ACS nano.

[10]  J. Shui,et al.  Phosphated IrMo bimetallic cluster for efficient hydrogen evolution reaction , 2022, eScience.

[11]  Qingsheng Gao,et al.  In-situ reconstruction of catalysts in cathodic electrocatalysis: New insights into active-site structures and working mechanisms , 2022, Journal of Energy Chemistry.

[12]  A. Bell,et al.  Highly selective and productive reduction of carbon dioxide to multicarbon products via in situ CO management using segmented tandem electrodes , 2022, Nature Catalysis.

[13]  Ruitao Lv,et al.  Rational catalyst design and interface engineering for electrochemical CO2 reduction to high-valued alcohols , 2022, Journal of Energy Chemistry.

[14]  Xun Hu,et al.  Beyond catalytic materials: Controlling local gas/liquid environment in the catalyst layer for CO2 electrolysis , 2022 .

[15]  Ya-li Guo,et al.  Unveiling the Synergy of O‐Vacancy and Heterostructure over MoO3‐x/MXene for N2 Electroreduction to NH3 , 2021, Advanced Energy Materials.

[16]  Yunqi Liu,et al.  In-situ construction of N-doped carbon nanosnakes encapsulated FeCoSe nanoparticles as efficient bifunctional electrocatalyst for overall water splitting , 2021, Journal of Energy Chemistry.

[17]  Yang Hou,et al.  Atomically Dispersed Zinc(I) Active Sites to Accelerate Nitrogen Reduction Kinetics for Ammonia Electrosynthesis , 2021, Advanced materials.

[18]  Qinglin Li,et al.  A General Strategy toward Metal Sulfide Nanoparticles Confined in a Sulfur-Doped Ti3 C2 Tx MXene 3D Porous Aerogel for Efficient Ambient N2 Electroreduction. , 2021, Small.

[19]  X. Qiu,et al.  Atomically Dispersed s-Block Magnesium Sites for Electroreduction of CO2 to CO. , 2021, Angewandte Chemie.

[20]  A. Du,et al.  Rhodium-molybdenum oxide electrocatalyst with dual active sites for electrochemical ammonia synthesis under neutral pH condition , 2021, Journal of Electroanalytical Chemistry.

[21]  Yifeng Han,et al.  Wettability control in electrocatalyst: A mini review , 2021, Journal of Energy Chemistry.

[22]  Tianyi Liu,et al.  Mesoscale Diffusion Enhancement of Carbon-Bowl-Shaped Nanoreactor toward High-Performance Electrochemical H2O2 Production. , 2021, ACS applied materials & interfaces.

[23]  Haotian Wang,et al.  Room-temperature electrochemical acetylene reduction to ethylene with high conversion and selectivity , 2021, Nature Catalysis.

[24]  Xiaodong Zhang,et al.  Porous catalytic membranes for CO2 conversion , 2021, Journal of Energy Chemistry.

[25]  Huanwen Wang,et al.  Abundant heterointerfaces in MOF-derived hollow CoS2–MoS2 nanosheet array electrocatalysts for overall water splitting , 2021 .

[26]  Mengfan Wang,et al.  Salting-out effect promoting highly efficient ambient ammonia synthesis , 2021, Nature Communications.

[27]  Y. Jiao,et al.  Tailoring Acidic Oxygen Reduction Selectivity on Single-Atom Catalysts via Modification of First and Second Coordination Spheres. , 2021, Journal of the American Chemical Society.

[28]  Xiaofeng Feng,et al.  Tuning the Microenvironment in Gas-Diffusion Electrodes Enables High-Rate CO2 Electrolysis to Formate , 2021 .

[29]  Mengfan Wang,et al.  Proton-filtering covalent organic frameworks with superior nitrogen penetration flux promote ambient ammonia synthesis , 2021, Nature Catalysis.

[30]  D. Sebők,et al.  Operando cathode activation with alkali metal cations for high current density operation of water-fed zero-gap carbon dioxide electrolyzers , 2021, Nature Energy.

[31]  B. Cheng,et al.  Rational design of hollow oxygen deficiency-enriched NiFe2O4@N/rGO as bifunctional electrocatalysts for overall water splitting , 2021, Journal of Energy Chemistry.

[32]  L. Dai,et al.  Boosting Electroreduction Kinetics of Nitrogen to Ammonia via Tuning Electron Distribution of Single-atomic Iron Sites. , 2021, Angewandte Chemie.

[33]  Nikola A. Dudukovic,et al.  3D‐Printable Fluoropolymer Gas Diffusion Layers for CO2 Electroreduction , 2021, Advanced materials.

[34]  Xun Hu,et al.  Enhancing carbon dioxide gas-diffusion electrolysis by creating a hydrophobic catalyst microenvironment , 2021, Nature communications.

[35]  Xijiang Han,et al.  Hollow FeCo-FeCoP@C nanocubes embedded in nitrogen-doped carbon nanocages for efficient overall water splitting , 2020, Journal of Energy Chemistry.

[36]  Guihua Yu,et al.  Gel-Derived Amorphous BiNi Alloy Promotes Electrocatalytic Nitrogen Fixation via Optimizing Nitrogen Adsorption and Activation. , 2020, Angewandte Chemie.

[37]  Yanyong Wang,et al.  Defect Chemistry in Heterogeneous Catalysis: Recognition, Understanding, and Utilization , 2020 .

[38]  T. Isimjan,et al.  Oxygen defect-rich double-layer hierarchical porous Co3O4 arrays as high-efficient oxygen evolution catalyst for overall water splitting , 2020, Journal of Energy Chemistry.

[39]  S. Xi,et al.  Axial modification of cobalt complexes on heterogeneous surface with enhanced electron transfer for carbon dioxide reduction. , 2020, Angewandte Chemie.

[40]  Tao Qian,et al.  Unveiling the Essential Nature of Lewis Basicity in Thermodynamically and Dynamically Promoted Nitrogen Fixation , 2020, Advanced Functional Materials.

[41]  Conggang Li,et al.  Coupling N2 and CO2 in H2O to synthesize urea under ambient conditions , 2020, Nature Chemistry.

[42]  Lei Jiang,et al.  Efficient wettability-controlled electroreduction of CO2 to CO at Au/C interfaces , 2020, Nature Communications.

[43]  Hiang Kwee Lee,et al.  ZIF-induced d-band Modification in Bimetallic Nanocatalyst: Achieving >44% Efficiency in Ambient Nitrogen Reduction Reaction. , 2020, Angewandte Chemie.

[44]  Zhong‐Yong Yuan,et al.  Surface/interface engineering of high-efficiency noble metal-free electrocatalysts for energy-related electrochemical reactions , 2020, Journal of Energy Chemistry.

[45]  Jihun Oh,et al.  Modulating Local CO2 Concentration as a General Strategy for Enhancing C−C Coupling in CO2 Electroreduction , 2020, Joule.

[46]  Shaobin Wang,et al.  Boosting alkaline hydrogen evolution and Zn–H2O cell induced by interfacial electron transfer , 2020 .

[47]  Qinghua Zhang,et al.  High-efficiency oxygen reduction to hydrogen peroxide catalyzed by Ni single atom catalysts with tetradentate N2O2 coordination in a three-phase flow cell. , 2020, Angewandte Chemie.

[48]  Hao Ming Chen,et al.  Electrochemical Reduction of CO2 to Ethane through Stabilization of an Ethoxy Intermediate. , 2020, Angewandte Chemie.

[49]  Jianhong Liu,et al.  Highly efficient utilization of single atoms via constructing 3D and free-standing electrodes for CO2 reduction with ultrahigh current density , 2020 .

[50]  Qiang Zhang,et al.  Coordination Tunes Selectivity: Two-Electron Oxygen Reduction on High-Loading Molybdenum Single-Atom Catalysts. , 2020, Angewandte Chemie.

[51]  David Sinton,et al.  CO2 electrolysis to multicarbon products at activities greater than 1 A cm−2 , 2020, Science.

[52]  Youyong Li,et al.  A General Strategy to Glassy M‐Te (M = Ru, Rh, Ir) Porous Nanorods for Efficient Electrochemical N2 Fixation , 2020, Advanced materials.

[53]  Xiaofeng Feng,et al.  Understanding the Electrocatalytic Interface for Ambient Ammonia Synthesis , 2020 .

[54]  Denise Handlarski Green , 2007, Definitions.

[55]  Jun Chen,et al.  Nanoporous Palladium Hydride for Electrocatalytic N2 Reduction under Ambient Conditions. , 2019, Angewandte Chemie.

[56]  P. Kenis,et al.  Durable Cathodes and Electrolyzers for the Efficient Aqueous Electrochemical Reduction of CO2. , 2019, ChemSusChem.

[57]  Christine M. Gabardo,et al.  Cooperative CO2-to-ethanol conversion via enriched intermediates at molecule–metal catalyst interfaces , 2019, Nature Catalysis.

[58]  M. Kim,et al.  Boosted Electron-Transfer Kinetics of Hydrogen Evolution Reaction at Bimetallic RhCo Alloy Nanotubes in Acidic Solution. , 2019, ACS applied materials & interfaces.

[59]  Christine M. Gabardo,et al.  Molecular tuning of CO2-to-ethylene conversion , 2019, Nature.

[60]  Christine M. Gabardo,et al.  Constraining CO coverage on copper promotes high-efficiency ethylene electroproduction , 2019, Nature Catalysis.

[61]  Z. Tian,et al.  Highly Selective Production of Ethylene by Electroreduction of Carbon Monoxide. , 2019, Angewandte Chemie.

[62]  Bin Wang,et al.  Core-branch CoNi hydroxysulfides with versatilely regulated electronic and surface structures for superior oxygen evolution electrocatalysis , 2019, Journal of Energy Chemistry.

[63]  D. Nocera,et al.  Artificial Photosynthesis at Efficiencies Greatly Exceeding That of Natural Photosynthesis. , 2019, Accounts of chemical research.

[64]  Fikile R. Brushett,et al.  Investigating Electrode Flooding in a Flowing Electrolyte, Gas-Fed Carbon Dioxide Electrolyzer. , 2019, ChemSusChem.

[65]  Yanyong Wang,et al.  Rational design of three-phase interfaces for electrocatalysis , 2019, Nano Research.

[66]  Mengfan Wang,et al.  Facilitating nitrogen accessibility to boron-rich covalent organic frameworks via electrochemical excitation for efficient nitrogen fixation , 2019, Nature Communications.

[67]  W. Goddard,et al.  Formation of carbon–nitrogen bonds in carbon monoxide electrolysis , 2019, Nature Chemistry.

[68]  S. Xi,et al.  Linkage Effect in the Heterogenization of Cobalt Complexes by Doped Graphene for Electrocatalytic CO 2 Reduction , 2019, Angewandte Chemie.

[69]  M. Fontecave,et al.  Bio-inspired hydrophobicity promotes CO2 reduction on a Cu surface , 2019, Nature Materials.

[70]  Jianhong Liu,et al.  Scalable Production of Efficient Single-Atom Copper Decorated Carbon Membranes for CO2 Electroreduction to Methanol. , 2019, Journal of the American Chemical Society.

[71]  D. Rentsch,et al.  Electrocatalytic Reduction of Gaseous CO2 to CO on Sn/Cu‐Nanofiber‐Based Gas Diffusion Electrodes , 2019, Proceedings of the nanoGe Fall Meeting 2019.

[72]  Michael B. Ross,et al.  Designing materials for electrochemical carbon dioxide recycling , 2019, Nature Catalysis.

[73]  Yu‐Fei Song,et al.  Unique NiFe NiCoO2 hollow polyhedron as bifunctional electrocatalysts for water splitting , 2019, Journal of Energy Chemistry.

[74]  Xiaobing Hu,et al.  Two-dimensional copper nanosheets for electrochemical reduction of carbon monoxide to acetate , 2019, Nature Catalysis.

[75]  Yafei Li,et al.  Photoelectrochemical Synthesis of Ammonia on the Aerophilic-Hydrophilic Heterostructure with 37.8% Efficiency , 2019, Chem.

[76]  W. Chu,et al.  Interfacial engineering of cobalt sulfide/graphene hybrids for highly efficient ammonia electrosynthesis , 2019, Proceedings of the National Academy of Sciences.

[77]  Matthew W. Kanan,et al.  Carbon Monoxide Gas Diffusion Electrolysis that Produces Concentrated C2 Products with High Single-Pass Conversion , 2019, Joule.

[78]  H. Xin,et al.  Atomically Dispersed Molybdenum Catalysts for Efficient Ambient Nitrogen Fixation. , 2019, Angewandte Chemie.

[79]  Stafford W. Sheehan,et al.  Progress toward Commercial Application of Electrochemical Carbon Dioxide Reduction , 2018, Chem.

[80]  Jun Luo,et al.  Interface engineering of Pt and CeO2 nanorods with unique interaction for methanol oxidation , 2018, Nano Energy.

[81]  Yanjie Hu,et al.  Unsaturated Sulfur Edge Engineering of Strongly Coupled MoS2 Nanosheet–Carbon Macroporous Hybrid Catalyst for Enhanced Hydrogen Generation , 2018, Advanced Energy Materials.

[82]  Hongliang Jiang,et al.  Structural Self-Reconstruction of Catalysts in Electrocatalysis. , 2018, Accounts of chemical research.

[83]  Hailiang Wang,et al.  Selectivity regulation of CO2 electroreduction through contact interface engineering on superwetting Cu nanoarray electrodes , 2018, Nano Research.

[84]  Shuangyin Wang,et al.  Rational Design of Transition Metal-Based Materials for Highly Efficient Electrocatalysis , 2018, Small Methods.

[85]  Xiaodong Sun,et al.  Tuning Gold Nanoparticles with Chelating Ligands for Highly Efficient Electrocatalytic CO2 Reduction. , 2018, Angewandte Chemie.

[86]  Feng Jiao,et al.  High-rate electroreduction of carbon monoxide to multi-carbon products , 2018, Nature Catalysis.

[87]  Allen Pei,et al.  Efficient electrocatalytic CO2 reduction on a three-phase interface , 2018, Nature Catalysis.

[88]  F. Gao,et al.  NiFe2O4 Nanoparticles/NiFe Layered Double-Hydroxide Nanosheet Heterostructure Array for Efficient Overall Water Splitting at Large Current Densities. , 2018, ACS applied materials & interfaces.

[89]  L. Gu,et al.  Corrosion engineering towards efficient oxygen evolution electrodes with stable catalytic activity for over 6000 hours , 2018, Nature Communications.

[90]  Shuhong Yu,et al.  Doping-induced structural phase transition in cobalt diselenide enables enhanced hydrogen evolution catalysis , 2018, Nature Communications.

[91]  Gengfeng Zheng,et al.  Single-Atomic Cu with Multiple Oxygen Vacancies on Ceria for Electrocatalytic CO2 Reduction to CH4 , 2018, ACS Catalysis.

[92]  Lei Jiang,et al.  Superwetting Electrodes for Gas-Involving Electrocatalysis. , 2018, Accounts of chemical research.

[93]  H. Jeong,et al.  Efficient Hydrogen Evolution Reaction Catalysis in Alkaline Media by All‐in‐One MoS2 with Multifunctional Active Sites , 2018, Advanced materials.

[94]  D. Macfarlane,et al.  Rational Electrode–Electrolyte Design for Efficient Ammonia Electrosynthesis under Ambient Conditions , 2018 .

[95]  C. Xiang,et al.  High-Rate Electrochemical Reduction of Carbon Monoxide to Ethylene Using Cu-Nanoparticle-Based Gas Diffusion Electrodes , 2018 .

[96]  D. Cullen,et al.  Unveiling Active Sites of CO2 Reduction on Nitrogen-Coordinated and Atomically Dispersed Iron and Cobalt Catalysts , 2018 .

[97]  Hiang Kwee Lee,et al.  Favoring the unfavored: Selective electrochemical nitrogen fixation using a reticular chemistry approach , 2018, Science Advances.

[98]  Qinghua Zhang,et al.  Ru Modulation Effects in the Synthesis of Unique Rod-like Ni@Ni2P-Ru Heterostructures and Their Remarkable Electrocatalytic Hydrogen Evolution Performance. , 2018, Journal of the American Chemical Society.

[99]  Qiang Zhang,et al.  Multiscale Principles To Boost Reactivity in Gas-Involving Energy Electrocatalysis. , 2018, Accounts of Chemical Research.

[100]  Qiang Zhang,et al.  A review of nanocarbons in energy electrocatalysis: Multifunctional substrates and highly active sites , 2017 .

[101]  R. Luque,et al.  3D Porous Carbonaceous Electrodes for Electrocatalytic Applications , 2017 .

[102]  Liping Chen,et al.  Enhanced Photocatalytic Reaction at Air-Liquid-Solid Joint Interfaces. , 2017, Journal of the American Chemical Society.

[103]  Yuhan Sun,et al.  Metal-Free Nitrogen-Doped Mesoporous Carbon for Electroreduction of CO2 to Ethanol. , 2017, Angewandte Chemie.

[104]  J. Savéant,et al.  Nanodiffusion in electrocatalytic films. , 2017, Nature materials.

[105]  X. Bao,et al.  Surface functionalization of ZIF-8 with ammonium ferric citrate toward high exposure of Fe-N active sites for efficient oxygen and carbon dioxide electroreduction , 2017 .

[106]  M. Antonietti,et al.  Efficient Electrocatalytic Reduction of CO2 by Nitrogen-Doped Nanoporous Carbon/Carbon Nanotube Membranes: A Step Towards the Electrochemical CO2 Refinery. , 2017, Angewandte Chemie.

[107]  S. Qiao,et al.  Surface and Interface Engineering of Noble-Metal-Free Electrocatalysts for Efficient Energy Conversion Processes. , 2017, Accounts of chemical research.

[108]  Colin F. Dickens,et al.  Combining theory and experiment in electrocatalysis: Insights into materials design , 2017, Science.

[109]  Lei Jiang,et al.  Highly Boosted Oxygen Reduction Reaction Activity by Tuning the Underwater Wetting State of the Superhydrophobic Electrode. , 2017, Small.

[110]  Ping Chen,et al.  Breaking scaling relations to achieve low-temperature ammonia synthesis through LiH-mediated nitrogen transfer and hydrogenation. , 2017, Nature chemistry.

[111]  Yuyan Shao,et al.  Advanced catalyst supports for PEM fuel cell cathodes , 2016 .

[112]  Shaojun Dong,et al.  Transition‐Metal (Co, Ni, and Fe)‐Based Electrocatalysts for the Water Oxidation Reaction , 2016, Advanced materials.

[113]  T. Asefa,et al.  Metal-Free and Noble Metal-Free Heteroatom-Doped Nanostructured Carbons as Prospective Sustainable Electrocatalysts. , 2016, Accounts of chemical research.

[114]  Lei Jiang,et al.  Superaerophilic Carbon‐Nanotube‐Array Electrode for High‐Performance Oxygen Reduction Reaction , 2016, Advanced materials.

[115]  Jinling He,et al.  Superaerophobic Electrode with Metal@Metal‐Oxide Powder Catalyst for Oxygen Evolution Reaction , 2016 .

[116]  C. Tung,et al.  Ultrafine NiO Nanosheets Stabilized by TiO2 from Monolayer NiTi-LDH Precursors: An Active Water Oxidation Electrocatalyst. , 2016, Journal of the American Chemical Society.

[117]  Jun Liu,et al.  Mesoporous materials for energy conversion and storage devices , 2016 .

[118]  Matteo Monai,et al.  Fundamentals and Catalytic Applications of CeO2-Based Materials. , 2016, Chemical reviews.

[119]  S. Qiao,et al.  Size Fractionation of Two-Dimensional Sub-Nanometer Thin Manganese Dioxide Crystals towards Superior Urea Electrocatalytic Conversion. , 2016, Angewandte Chemie.

[120]  Guido Mul,et al.  Three-dimensional porous hollow fibre copper electrodes for efficient and high-rate electrochemical carbon dioxide reduction , 2016, Nature Communications.

[121]  Zhixiong Cai,et al.  Electrodeposition‐Assisted Synthesis of Ni2P Nanosheets on 3D Graphene/Ni Foam Electrode and Its Performance for Electrocatalytic Hydrogen Production , 2015 .

[122]  Y. Jiao,et al.  Engineering of Carbon‐Based Electrocatalysts for Emerging Energy Conversion: From Fundamentality to Functionality , 2015, Advanced materials.

[123]  Lei Jiang,et al.  Bioinspired Surfaces with Superwettability: New Insight on Theory, Design, and Applications. , 2015, Chemical reviews.

[124]  L. Dai,et al.  Carbon-based electrocatalysts for advanced energy conversion and storage , 2015, Science Advances.

[125]  Lei Jiang,et al.  Under‐Water Superaerophobic Pine‐Shaped Pt Nanoarray Electrode for Ultrahigh‐Performance Hydrogen Evolution , 2015 .

[126]  M. Jaroniec,et al.  Porous C3N4 nanolayers@N-graphene films as catalyst electrodes for highly efficient hydrogen evolution. , 2015, ACS nano.

[127]  Jun Wang,et al.  ZIF-8 derived graphene-based nitrogen-doped porous carbon sheets as highly efficient and durable oxygen reduction electrocatalysts. , 2014, Angewandte Chemie.

[128]  Thomas F. Jaramillo,et al.  Catalyzing the Hydrogen Evolution Reaction (HER) with Molybdenum Sulfide Nanomaterials , 2014 .

[129]  Hao Wang,et al.  Ultrahigh Hydrogen Evolution Performance of Under‐Water “Superaerophobic” MoS2 Nanostructured Electrodes , 2014, Advanced materials.

[130]  Hua Zhang,et al.  Ni3S2 nanorods/Ni foam composite electrode with low overpotential for electrocatalytic oxygen evolution , 2013 .

[131]  E. Riedo,et al.  The interplay between apparent viscosity and wettability in nanoconfined water , 2013, Nature Communications.

[132]  B. Fang,et al.  MoS2 Nanosheets: A Designed Structure with High Active Site Density for the Hydrogen Evolution Reaction , 2013 .

[133]  Jacek K. Stolarczyk,et al.  Photocatalytic reduction of CO2 on TiO2 and other semiconductors. , 2013, Angewandte Chemie.

[134]  Qiang Xu,et al.  Metal–organic frameworks as platforms for clean energy , 2013 .

[135]  Paul J. A. Kenis,et al.  Electrochemical conversion of CO2 to useful chemicals: current status, remaining challenges, and future opportunities , 2013 .

[136]  Fikile R. Brushett,et al.  The Effects of Catalyst Layer Deposition Methodology on Electrode Performance , 2013 .

[137]  M. Gomes,et al.  Solubility of carbon dioxide, nitrous oxide, ethane, and nitrogen in 1-butyl-1-methylpyrrolidinium and trihexyl(tetradecyl)phosphonium tris(pentafluoroethyl)trifluorophosphate (eFAP) ionic liquids , 2013 .

[138]  Matthew W. Kanan,et al.  Aqueous CO2 reduction at very low overpotential on oxide-derived Au nanoparticles. , 2012, Journal of the American Chemical Society.

[139]  Jakob Kibsgaard,et al.  Engineering the surface structure of MoS2 to preferentially expose active edge sites for electrocatalysis. , 2012, Nature materials.

[140]  A. Majumdar,et al.  Opportunities and challenges for a sustainable energy future , 2012, Nature.

[141]  Nasri Sulaiman,et al.  Influencing factors of water electrolysis electrical efficiency , 2012 .

[142]  X. Lou,et al.  Growth of ultrathin mesoporous Co3O4 nanosheet arrays on Ni foam for high-performance electrochemical capacitors , 2012 .

[143]  Klaus Müllen,et al.  Graphene-based carbon nitride nanosheets as efficient metal-free electrocatalysts for oxygen reduction reactions. , 2011, Angewandte Chemie.

[144]  Ib Chorkendorff,et al.  The Pt(111)/electrolyte interface under oxygen reduction reaction conditions: an electrochemical impedance spectroscopy study. , 2011, Langmuir : the ACS journal of surfaces and colloids.

[145]  Yuh-Shan Ho,et al.  Gas diffusion layer for proton exchange membrane fuel cells—A review , 2009 .

[146]  Lei Jiang,et al.  Air bubble bursting effect of lotus leaf. , 2009, Langmuir : the ACS journal of surfaces and colloids.

[147]  W. Winiwarter,et al.  How a century of ammonia synthesis changed the world , 2008 .

[148]  Lei Jiang,et al.  Definition of Superhydrophobic States , 2007 .

[149]  Z. Shao,et al.  Electrodepositing Pt by modulated pulse current on a nafion-bonded carbon substrate as an electrode for PEMFC , 2007 .

[150]  Yuyan Shao,et al.  Proton exchange membrane fuel cell from low temperature to high temperature: Material challenges , 2007 .

[151]  Trung Van Nguyen,et al.  Effect of Thickness and Hydrophobic Polymer Content of the Gas Diffusion Layer on Electrode Flooding Level in a PEMFC , 2005 .

[152]  John A. Turner,et al.  Sustainable Hydrogen Production , 2004, Science.

[153]  Yoshio Hori,et al.  Electrochemical Reduction of Carbon Dioxide at a Platinum Electrode in Acetonitrile‐Water Mixtures , 2000 .

[154]  K. Kreuer Proton Conductivity: Materials and Applications , 1996 .

[155]  J. A. Harrison,et al.  The role of gas bubble formation in the electro-catalysis of the hydrogen evolution reaction , 1983 .

[156]  Wenjun Zheng,et al.  Defect and interface engineering for electrochemical nitrogen reduction reaction under ambient conditions , 2022 .