Atomic-level tuning of Co–N–C catalyst for high-performance electrochemical H2O2 production
暂无分享,去创建一个
Taeghwan Hyeon | Jiheon Kim | Yung-Eun Sung | Hyeon Seok Lee | Kug-Seung Lee | Heejong Shin | Jong Suk Yoo | T. Hyeon | Y. Sung | Kug‐Seung Lee | Jiheon Kim | Euiyeon Jung | Heejong Shin | Sung-Pyo Cho | Suhyeong Lee | Byoung-Hoon Lee | Euiyeon Jung | Vladimir Efremov | Wytse Hooch Antink | Subin Park | B. Lee | Wytse Hooch Antink | Subin Park | Sung-pyo Cho | V. Efremov | Suhyeong Lee | H. Lee
[1] Taeghwan Hyeon,et al. Reversible and cooperative photoactivation of single-atom Cu/TiO2 photocatalysts , 2019, Nature Materials.
[2] Yuyan Shao,et al. Iron‐Free Cathode Catalysts for Proton‐Exchange‐Membrane Fuel Cells: Cobalt Catalysts and the Peroxide Mitigation Approach , 2019, Advanced materials.
[3] J. H. Kim,et al. Active Edge-Site-Rich Carbon Nanocatalysts with Enhanced Electron Transfer for Efficient Electrochemical Hydrogen Peroxide Production. , 2019, Angewandte Chemie.
[4] Evan C. Wegener,et al. Highly active atomically dispersed CoN4 fuel cell cathode catalysts derived from surfactant-assisted MOFs: carbon-shell confinement strategy , 2019, Energy & Environmental Science.
[5] L. Stievano,et al. The Achilles' heel of iron-based catalysts during oxygen reduction in an acidic medium , 2018 .
[6] D. Cullen,et al. Atomically dispersed manganese catalysts for oxygen reduction in proton-exchange membrane fuel cells , 2018, Nature Catalysis.
[7] Michel Dupuis,et al. Water oxidation on a mononuclear manganese heterogeneous catalyst , 2018, Nature Catalysis.
[8] Paul N. Duchesne,et al. Golden single-atomic-site platinum electrocatalysts , 2018, Nature Materials.
[9] D. Sokaras,et al. Designing Boron Nitride Islands in Carbon Materials for Efficient Electrochemical Synthesis of Hydrogen Peroxide. , 2018, Journal of the American Chemical Society.
[10] Tao Zhang,et al. Heterogeneous single-atom catalysis , 2018, Nature Reviews Chemistry.
[11] Bin Wang,et al. A Bimetallic Zn/Fe Polyphthalocyanine-Derived Single-Atom Fe-N4 Catalytic Site:A Superior Trifunctional Catalyst for Overall Water Splitting and Zn-Air Batteries. , 2018, Angewandte Chemie.
[12] Bin Wang,et al. A Bimetallic Zn/Fe Polyphthalocyanine-Derived Single-Atom Fe-N4 Catalytic Site:A Superior Trifunctional Catalyst for Overall Water Splitting and Zn-Air Batteries. , 2018, Angewandte Chemie.
[13] Michael B. Ross,et al. Efficient hydrogen peroxide generation using reduced graphene oxide-based oxygen reduction electrocatalysts , 2018, Nature Catalysis.
[14] Ib Chorkendorff,et al. Toward the Decentralized Electrochemical Production of H2O2: A Focus on the Catalysis , 2018 .
[15] Tao Zhang,et al. Atomically dispersed Ni(i) as the active site for electrochemical CO2 reduction , 2018 .
[16] Yu Huang,et al. General synthesis and definitive structural identification of MN4C4 single-atom catalysts with tunable electrocatalytic activities , 2018, Nature Catalysis.
[17] Yayuan Liu,et al. High-efficiency oxygen reduction to hydrogen peroxide catalysed by oxidized carbon materials , 2018, Nature Catalysis.
[18] Karren L. More,et al. Direct atomic-level insight into the active sites of a high-performance PGM-free ORR catalyst , 2017, Science.
[19] Rose Amal,et al. Epitaxial Growth of Au–Pt–Ni Nanorods for Direct High Selectivity H2O2 Production , 2016, Advanced materials.
[20] L. Gu,et al. Photochemical route for synthesizing atomically dispersed palladium catalysts , 2016, Science.
[21] Jiwhan Kim,et al. Single-Atom Catalyst of Platinum Supported on Titanium Nitride for Selective Electrochemical Reactions. , 2016, Angewandte Chemie.
[22] J. Grossman,et al. Atomistic understandings of reduced graphene oxide as an ultrathin-film nanoporous membrane for separations , 2015, Nature Communications.
[23] Frédéric Jaouen,et al. Identification of catalytic sites for oxygen reduction in iron- and nitrogen-doped graphene materials. , 2015, Nature materials.
[24] J. Valentine,et al. Superoxide Dismutases and Superoxide Reductases , 2014, Chemical reviews.
[25] Ib Chorkendorff,et al. Trends in the electrochemical synthesis of H2O2: enhancing activity and selectivity by electrocatalytic site engineering. , 2014, Nano letters.
[26] Eila,et al. Graphene Oxide Synthesized by using Modified Hummers Approach , 2014 .
[27] M. Matheron,et al. Molecular engineering of a cobalt-based electrocatalytic nanomaterial for H₂ evolution under fully aqueous conditions. , 2013, Nature chemistry.
[28] Ib Chorkendorff,et al. Enabling direct H2O2 production through rational electrocatalyst design. , 2013, Nature materials.
[29] S. Dahl,et al. The effect of ammonia upon the electrocatalysis of hydrogen oxidation and oxygen reduction on polycrystalline platinum , 2012 .
[30] Da Chen,et al. Graphene oxide: preparation, functionalization, and electrochemical applications. , 2012, Chemical reviews.
[31] Itai Panas,et al. Single atom hot-spots at Au-Pd nanoalloys for electrocatalytic H2O2 production. , 2011, Journal of the American Chemical Society.
[32] S. Mukerjee,et al. Influence of Inner- and Outer-Sphere Electron Transfer Mechanisms during Electrocatalysis of Oxygen Reduction in Alkaline Media , 2011 .
[33] Jan Rossmeisl,et al. Density functional studies of functionalized graphitic materials with late transition metals for Oxygen Reduction Reactions. , 2011, Physical chemistry chemical physics : PCCP.
[34] John Kitchin,et al. Universality in Oxygen Evolution Electrocatalysis on Oxide Surfaces , 2011 .
[35] Jan Rossmeisl,et al. Universality in Oxygen Evolution Electrocatalysis on Oxide , 2011 .
[36] D. Schiffrin,et al. Kinetics of electrocatalytic reduction of oxygen and hydrogen peroxide on dispersed gold nanoparticles. , 2010, Physical chemistry chemical physics : PCCP.
[37] Vivek B Shenoy,et al. Structural evolution during the reduction of chemically derived graphene oxide. , 2010, Nature chemistry.
[38] Satoshi Tazawa,et al. Catalytic synthesis of neutral hydrogen peroxide at a CoN2Cx cathode of a polymer electrolyte membrane fuel cell (PEMFC). , 2010, ChemSusChem.
[39] Deryn Chu,et al. Unraveling Oxygen Reduction Reaction Mechanisms on Carbon-Supported Fe-Phthalocyanine and Co-Phthalocyanine Catalysts in Alkaline Solutions , 2009 .
[40] Simultaneous nitrogen doping and reduction of graphene oxide. , 2009, Journal of the American Chemical Society.
[41] G. Hutchings,et al. Switching Off Hydrogen Peroxide Hydrogenation in the Direct Synthesis Process , 2009, Science.
[42] Ture R. Munter,et al. Scaling properties of adsorption energies for hydrogen-containing molecules on transition-metal surfaces. , 2007, Physical review letters.
[43] J. Fierro,et al. Hydrogen peroxide synthesis: an outlook beyond the anthraquinone process. , 2006, Angewandte Chemie.
[44] H. Jónsson,et al. Origin of the Overpotential for Oxygen Reduction at a Fuel-Cell Cathode. , 2004, The journal of physical chemistry. B.
[45] J. Nørskov,et al. Improved adsorption energetics within density-functional theory using revised Perdew-Burke-Ernzerhof functionals , 1999 .
[46] Kresse,et al. Efficient iterative schemes for ab initio total-energy calculations using a plane-wave basis set. , 1996, Physical review. B, Condensed matter.
[47] Blöchl,et al. Projector augmented-wave method. , 1994, Physical review. B, Condensed matter.
[48] E R James,et al. Superoxide dismutase. , 1994, Parasitology today.
[49] H. Monkhorst,et al. SPECIAL POINTS FOR BRILLOUIN-ZONE INTEGRATIONS , 1976 .
[50] I. Fridovich,et al. Superoxide dismutase. An enzymic function for erythrocuprein (hemocuprein). , 1969, The Journal of biological chemistry.
[51] J. ABELLO PASCUAL. [Production of hydrogen peroxide]. , 1954, Anales de la Real Academia de Farmacia.