The mechanism of high electrocatalytic activity and stability of the Pt3Co alloy embedded into the lattice by Au or Rh atoms
暂无分享,去创建一个
Hao Zheng | Yang Lijuan | Cui Yuhui | Lu Jinghao | Wu Runjin | L. Qian | Xu Shijia | Yang Libin
[1] P. Gao,et al. The mechanism of Co oxyhydroxide nano-islands deposited on a Pt surface to promote the oxygen reduction reaction at the cathode of fuel cells , 2020, RSC advances.
[2] Jun Lu,et al. Enhancing Oxygen Reduction Activity of Pt‐based Electrocatalysts: From Theoretical Mechanisms to Practical Methods , 2020 .
[3] Min Sun,et al. Shape-tunable Pt–Ag nanocatalysts with excellent performance for oxygen reduction reaction , 2020, International Journal of Hydrogen Energy.
[4] L. Gu,et al. Coordination structure dominated performance of single-atomic Pt catalyst for anti-Markovnikov hydroboration of alkenes , 2020, Science China Materials.
[5] Jun Lu,et al. Enhancing Oxygen Reduction Activity of Pt-based Electrocatalysts: from Theoretical Mechanisms to Practical Methods. , 2020, Angewandte Chemie.
[6] L. Gu,et al. Single-atom Rh/N-doped carbon electrocatalyst for formic acid oxidation , 2020, Nature Nanotechnology.
[7] Ying Dai,et al. Multifunctional electrocatalyst PtM with low Pt loading and high activity towards hydrogen and oxygen electrode reactions: A computational study , 2019, Applied Catalysis B: Environmental.
[8] Hyunjoo J. Lee,et al. Au-doped PtCo/C catalyst preventing Co leaching for proton exchange membrane fuel cells , 2019, Applied Catalysis B: Environmental.
[9] Jinlong Yang,et al. Atomically dispersed iron hydroxide anchored on Pt for preferential oxidation of CO in H2 , 2019, Nature.
[10] E. Easton,et al. A hydrothermal approach to access active and durable sulfonated silica-ceramic carbon electrodes for PEM fuel cell applications , 2018, Applied Catalysis B: Environmental.
[11] Hyunjoo J. Lee,et al. Gram-scale synthesis of highly active and durable octahedral PtNi nanoparticle catalysts for proton exchange membrane fuel cell , 2018, Applied Catalysis B: Environmental.
[12] Soo‐Kil Kim,et al. Electrodeposition-fabricated PtCu-alloy cathode catalysts for high-temperature proton exchange membrane fuel cells , 2018, Korean Journal of Chemical Engineering.
[13] J. Nørskov,et al. Understanding Catalytic Activity Trends in the Oxygen Reduction Reaction. , 2018, Chemical reviews.
[14] R. Lin,et al. Activity and Stability of Pt/C and Pt-Cu/C Electrocatalysts , 2018, Electrocatalysis.
[15] E. Antolini. Alloy vs. intermetallic compounds: Effect of the ordering on the electrocatalytic activity for oxygen reduction and the stability of low temperature fuel cell catalysts , 2017 .
[16] L. Gu,et al. Highly Active and Durable Pt72Ru28 Porous Nanoalloy Assembled with Sub‐4.0 nm Particles for Methanol Oxidation , 2017 .
[17] J. Sohn,et al. Fe/N/S-doped mesoporous carbon nanostructures as electrocatalysts for oxygen reduction reaction in acid medium , 2017 .
[18] Travis J Omasta,et al. Activity and Durability of Pt-Ni Nanocage Electocatalysts in Proton Exchange Membrane Fuel Cells , 2017 .
[19] T. Napporn,et al. Temperature-dependence of oxygen reduction activity on Pt/C and PtCr/C electrocatalysts synthesized from microwave-heated diethylene glycol method , 2017 .
[20] Qian-nan Wang,et al. Co@Pt Core@Shell nanoparticles encapsulated in porous carbon derived from zeolitic imidazolate framework 67 for oxygen electroreduction in alkaline media , 2017 .
[21] Y. Shul,et al. Synthesis of Durable Small-sized Bilayer Au@Pt Nanoparticles for High Performance PEMFC Catalysts , 2017 .
[22] K. Jiang,et al. Phase and Interface Engineering of Platinum-Nickel Nanowires for Efficient Electrochemical Hydrogen Evolution. , 2016, Angewandte Chemie.
[23] Chang Won Yoon,et al. Base tolerant polybenzimidazolium hydroxide membranes for solid alkaline-exchange membrane fuel cells , 2016 .
[24] Dong Su,et al. Surface engineering of hierarchical platinum-cobalt nanowires for efficient electrocatalysis , 2016, Nature Communications.
[25] Hongli Liu,et al. Efficient and selective aerobic oxidation of alcohols catalysed by MOF-derived Co catalysts , 2016 .
[26] Jens Kehlet. Modification of the surface electronic and chemical properties of Pt(111) by subsurface 3d transition metals , 2016 .
[27] D. Jeong,et al. Catalytic activity for oxygen reduction reaction on platinum-based core-shell nanoparticles: all-electron density functional theory. , 2015, Nanoscale.
[28] X. Lou,et al. Platinum multicubes prepared by ni(2+) -mediated shape evolution exhibit high electrocatalytic activity for oxygen reduction. , 2015, Angewandte Chemie.
[29] Li Li,et al. Recent advancements in Pt and Pt-free catalysts for oxygen reduction reaction. , 2015, Chemical Society reviews.
[30] Shuhong Yu,et al. Carbon-supported PtCo2Ni2 alloy with enhanced activity and stability for oxygen reduction , 2015, Science China Materials.
[31] J. Vanhellemont,et al. Estimation of the temperature dependent interaction between uncharged point defects in Si , 2015 .
[32] S. Nam,et al. Effect of gold subsurface layer on the surface activity and segregation in Pt/Au/Pt3M (where M = 3d transition metals) alloy catalyst from first-principles. , 2015, The Journal of chemical physics.
[33] Yuehua Wu,et al. FePt nanodendrites with high-index facets as active electrocatalysts for oxygen reduction reaction , 2015 .
[34] Xiaoming Sun,et al. Ultrathin dendritic Pt3Cu triangular pyramid caps with enhanced electrocatalytic activity. , 2014, ACS applied materials & interfaces.
[35] J. Ziegelbauer,et al. In Situ Spectroscopic Evidence for Ordered Core–Ultrathin Shell Pt1Co1 Nanoparticles with Enhanced Activity and Stability as Oxygen Reduction Electrocatalysts , 2014 .
[36] Karren L. More,et al. Highly Crystalline Multimetallic Nanoframes with Three-Dimensional Electrocatalytic Surfaces , 2014, Science.
[37] Ji-Hoon Jang,et al. One-pot sonication-assisted polyol synthesis of trimetallic core–shell (Pd,Co)@Pt nanoparticles for enhanced electrocatalysis , 2014 .
[38] K. Viswanathan,et al. Spectroscopic (FT-IR, FT-Raman), first order hyperpolarizability, NBO analysis, HOMO and LUMO analysis of 2,4-bis(2-methoxyphenyl)-1-phenylanthracene-9,10-dione by ab initio HF and density functional methods. , 2014, Spectrochimica acta. Part A, Molecular and biomolecular spectroscopy.
[39] Dae Jong You,et al. Communication: Enhanced oxygen reduction reaction and its underlying mechanism in Pd-Ir-Co trimetallic alloys. , 2013, The Journal of chemical physics.
[40] Malika Ammam. Polyoxometalates: formation, structures, principal properties, main deposition methods and application in sensing , 2013 .
[41] Shengli Chen,et al. Comparative Study of Oxygen Reduction Reaction Mechanisms on the Pd(111) and Pt(111) Surfaces in Acid Medium by DFT , 2013 .
[42] Ya‐Wen Zhang,et al. Ru nanocrystals with shape-dependent surface-enhanced Raman spectra and catalytic properties: controlled synthesis and DFT calculations. , 2012, Journal of the American Chemical Society.
[43] Enrico Negro,et al. Synthesis-structure-morphology interplay of bimetallic "core-shell" carbon nitride nano-electrocatalysts. , 2012, ChemSusChem.
[44] J. Ying,et al. Morphology and lateral strain control of Pt nanoparticles via core-shell construction using alloy AgPd core toward oxygen reduction reaction. , 2012, ACS nano.
[45] Fengjia Fan,et al. Mixed‐PtPd‐Shell PtPdCu Nanoparticle Nanotubes Templated from Copper Nanowires as Efficient and Highly Durable Electrocatalysts , 2012 .
[46] Jens K Nørskov,et al. Unifying the 2e(-) and 4e(-) Reduction of Oxygen on Metal Surfaces. , 2012, The journal of physical chemistry letters.
[47] T. Gordon,et al. Synthesis, shape control, and methanol electro-oxidation properties of Pt-Zn alloy and Pt3Zn intermetallic nanocrystals. , 2012, ACS nano.
[48] Ji-Hoon Jang,et al. One-pot synthesis of core–shell-like Pt3Co nanoparticle electrocatalyst with Pt-enriched surface for oxygen reduction reaction in fuel cells , 2011 .
[49] Peter Strasser,et al. Dealloyed binary PtM3 (M = Cu, Co, Ni) and ternary PtNi3M (M = Cu, Co, Fe, Cr) electrocatalysts for the oxygen reduction reaction: Performance in polymer electrolyte membrane fuel cells , 2011 .
[50] Hyunjoon Lee,et al. Platinum dendrites with controlled sizes for oxygen reduction reaction , 2010 .
[51] Younan Xia,et al. Shape-controlled synthesis of platinum nanocrystals for catalytic and electrocatalytic applications , 2009 .
[52] Shouheng Sun,et al. A general approach to the size- and shape-controlled synthesis of platinum nanoparticles and their catalytic reduction of oxygen. , 2008, Angewandte Chemie.
[53] P. Strasser,et al. Electrocatalysis on bimetallic surfaces: modifying catalytic reactivity for oxygen reduction by voltammetric surface dealloying. , 2007, Journal of the American Chemical Society.
[54] Michael F. Toney,et al. Structure-activity-stability relationships of Pt-Co alloy electrocatalysts in gas-diffusion electrode layers , 2007 .
[55] Bongjin Simon Mun,et al. Trends in electrocatalysis on extended and nanoscale Pt-bimetallic alloy surfaces. , 2007, Nature materials.
[56] Hermann Kronberger,et al. Contaminant absorption and conductivity in polymer electrolyte membranes , 2005 .
[57] Huifeng Qian,et al. CdTe@Co(OH)2 (core-shell) nanoparticles: aqueous synthesis and characterization. , 2005, Chemical communications.
[58] H. Gasteiger,et al. Activity benchmarks and requirements for Pt, Pt-alloy, and non-Pt oxygen reduction catalysts for PEMFCs , 2005 .
[59] H. Jónsson,et al. Origin of the Overpotential for Oxygen Reduction at a Fuel-Cell Cathode , 2004 .
[60] J. G. Chen,et al. Role of strain and ligand effects in the modification of the electronic and chemical properties of bimetallic surfaces. , 2004, Physical review letters.
[61] J. G. Chen,et al. Modification of the surface electronic and chemical properties of Pt(111) by subsurface 3d transition metals. , 2004, The Journal of chemical physics.