Oxygen Evolution Reaction Dynamics, Faradaic Charge Efficiency, and the Active Metal Redox States of Ni-Fe Oxide Water Splitting Electrocatalysts.
about
Enhancing Oxygen Evolution Reaction at High Current Densities on Amorphous-Like Ni-Fe-S Ultrathin Nanosheets via Oxygen Incorporation and Electrochemical Tuning.Characterization of NiFe oxyhydroxide electrocatalysts by integrated electronic structure calculations and spectroelectrochemistry.NiZn double hydroxide nanosheet-anchored nitrogen-doped graphene enriched with the γ-NiOOH phase as an activity modulated water oxidation electrocatalyst.Trimetallic Oxyhydroxide Coralloids for Efficient Oxygen Evolution Electrocatalysis.Influence of iron doping on tetravalent nickel content in catalytic oxygen evolving films.Scalable Fabrication of Highly Active and Durable Membrane Electrodes toward Water Oxidation.First-Row Transition Metal Based Catalysts for the Oxygen Evolution Reaction under Alkaline Conditions: Basic Principles and Recent Advances.Synergistic Effect of Cobalt and Iron in Layered Double Hydroxide Catalysts for the Oxygen Evolution Reaction.Highly Active Fe Sites in Ultrathin Pyrrhotite Fe7S8 Nanosheets Realizing Efficient Electrocatalytic Oxygen Evolution.A Highly Efficient Oxygen Evolution Catalyst Consisting of Interconnected Nickel-Iron-Layered Double Hydroxide and Carbon Nanodomains.Hierarchical Hollow Nanoprisms Based on Ultrathin Ni-Fe Layered Double Hydroxide Nanosheets with Enhanced Electrocatalytic Activity towards Oxygen Evolution.Phosphorus and Fluorine Co-Doping Induced Enhancement of Oxygen Evolution Reaction in Bimetallic Nitride Nanorods Arrays: Ionic Liquid-Driven and Mechanism Clarification.The role of carbonate in electro-catalytic water oxidation by using Ni(1,4,8,11-tetraazacyclotetradecane)2.Facile Spray-Pyrolysis Synthesis of Yolk-Shell Earth-Abundant Elemental Nickel-Iron-Based Nanohybrid Electrocatalysts for Full Water Splitting.How many surface atoms in Co3O4 take part in oxygen evolution? Isotope labeling together with differential electrochemical mass spectrometry.Boosting the Performance of the Nickel Anode in the Oxygen Evolution Reaction by Simple Electrochemical Activation.Preparation and phase transition of FeOOH nanorods: strain effects on catalytic water oxidation.Chemical Valence-Dependent Electrocatalytic Activity for Oxygen Evolution Reaction: A Case of Nickel Sulfides Hybridized with N and S Co-Doped Carbon Nanoparticles.Ni-Fe Nitride Nanoplates on Nitrogen-Doped Graphene as a Synergistic Catalyst for Reversible Oxygen Evolution Reaction and Rechargeable Zn-Air Battery.Boosting Bifunctional Oxygen Electrolysis for N-Doped Carbon via Bimetal Addition.Intralayered Ostwald Ripening to Ultrathin Nanomesh Catalyst with Robust Oxygen-Evolving Performance.In situ/Operando studies of electrocatalysts using hard X-ray spectroscopy.In situ formation of molecular Ni-Fe active sites on heteroatom-doped graphene as a heterogeneous electrocatalyst toward oxygen evolution.Value added transformation of ubiquitous substrates into highly efficient and flexible electrodes for water splitting.Catalysis by design: development of a bifunctional water splitting catalyst through an operando measurement directed optimization cycleRemarkably enhanced water splitting activity of nickel foam due to simple immersion in a ferric nitrate solutionHybrid Organic-Inorganic Transition-Metal Phosphonates as Precursors for Water Oxidation ElectrocatalystsNi/NiOx-decorated carbon nanofibers with enhanced oxygen evolution activity for rechargeable zinc–air batteries
P2860
Q37710950-541158A7-6A1F-4CDB-81AD-CD5D2DFBF9D1Q37730199-C9E0A4C6-8381-40B2-AD7A-D2AAD88AE088Q38640409-DCB3CA0E-E9A0-4B08-945F-D67CCC44796BQ41933077-EFEB2CFC-BEB1-460F-9931-2E7736ACEBC1Q42320405-20081BD5-726B-4BC0-9CD1-6EA6819A22D6Q46259475-EA90DD2C-682F-4FF8-BDF5-51C518553F12Q46299041-3F8089F2-7DA0-4396-86BA-5FDA7350496BQ46457311-D379CDC8-44F6-45D9-AC1A-1EC132AF05ADQ47101098-E69C6F36-B0BA-4CF8-BEBB-BD4792691DBAQ47262955-0CC904BC-9DAD-4178-96CB-94C5A866D4D7Q47311552-4EB2C840-57E2-4190-BE22-F75495962E3AQ47677270-5B773B19-F08D-48D5-A088-F0F96BCC68B8Q47864067-CDF051A4-9441-49D3-97BA-95AAC5FB6739Q47912775-87CEFA94-995E-4AD6-B2E5-2AE6A1D194D9Q47993842-C3F87519-0F9B-4D51-8AD2-59BE48620C9DQ48043808-256BE165-07D0-48E7-9B8D-26EC8D816B1FQ48093732-48B1B0CA-035E-4278-AAFE-1234644BBF6AQ49497079-81757AAE-A5E1-47CE-B3C4-03FFB0F706A4Q50873232-8CC99516-BAD5-4628-94E1-F6CBA09C539DQ50892400-81A6D490-6280-478B-B5B4-3BC1ED3D810CQ51057702-CB3B3FCA-3920-4BAF-9CD5-0020C07F3E0AQ51743260-D1C54C07-AD8B-4DC6-A180-956BC84CDF7EQ52656951-143FF3FF-88E4-482D-91A1-F70ECD6D0628Q55146324-53A60C7A-9593-4716-96EE-2ACC147BAC2AQ56890324-49EEA3A5-141D-4B4C-BBAF-8D39563E5CACQ57632920-5094503B-D363-402C-AE43-B3D42EACBA31Q58208050-E320B528-3804-4A3A-8FA5-95D31635667FQ59032001-3FDCF762-1C50-480A-BD18-B75313572784
P2860
Oxygen Evolution Reaction Dynamics, Faradaic Charge Efficiency, and the Active Metal Redox States of Ni-Fe Oxide Water Splitting Electrocatalysts.
description
2016 nî lūn-bûn
@nan
2016年の論文
@ja
2016年論文
@yue
2016年論文
@zh-hant
2016年論文
@zh-hk
2016年論文
@zh-mo
2016年論文
@zh-tw
2016年论文
@wuu
2016年论文
@zh
2016年论文
@zh-cn
name
Oxygen Evolution Reaction Dyna ...... er Splitting Electrocatalysts.
@en
Oxygen Evolution Reaction Dyna ...... er Splitting Electrocatalysts.
@nl
type
label
Oxygen Evolution Reaction Dyna ...... er Splitting Electrocatalysts.
@en
Oxygen Evolution Reaction Dyna ...... er Splitting Electrocatalysts.
@nl
prefLabel
Oxygen Evolution Reaction Dyna ...... er Splitting Electrocatalysts.
@en
Oxygen Evolution Reaction Dyna ...... er Splitting Electrocatalysts.
@nl
P2093
P356
P1476
Oxygen Evolution Reaction Dyna ...... ter Splitting Electrocatalysts
@en
P2093
Benjamin Paul
Holger Dau
Jorge Ferreira de Araújo
Mikaela Görlin
Peter Strasser
Ralph Krähnert
Sören Dresp
Tobias Reier
P304
P356
10.1021/JACS.6B00332
P407
P577
2016-04-26T00:00:00Z