Dissolution of platinum: limits for the deployment of electrochemical energy conversion?
about
Dissolution of Platinum in the Operational Range of Fuel Cells.Intermediate stages of electrochemical oxidation of single-crystalline platinum revealed by in situ Raman spectroscopy.Platinum recycling going green via induced surface potential alteration enabling fast and efficient dissolution.Real-Time Optical Monitoring of Pt Catalyst Under the Potentiodynamic Conditions.Bulk layered heterojunction as an efficient electrocatalyst for hydrogen evolution.Tailoring the catalytic activity of electrodes with monolayer amounts of foreign metals.Techniques and methodologies in modern electrocatalysis: evaluation of activity, selectivity and stability of catalytic materials.Porous inorganic nanostructures with colloidal dimensions: synthesis and applications in electrochemical energy devices.Electrochemistry of nanoparticles.Design criteria for stable Pt/C fuel cell catalysts.Modelling oxide formation and growth on platinum.The Stability Challenge on the Pathway to Low and Ultra-Low Platinum Loading for Oxygen Reduction in Fuel Cells.In search of lost platinum.Reconstruction and dissolution of shape-controlled Pt nanoparticles in acidic electrolytes.Stability of Fe-N-C Catalysts in Acidic Medium Studied by Operando Spectroscopy.Tuning the Composition and Structure of Amorphous Molybdenum Sulfide/Carbon Black Nanocomposites by Radiation Technique for Highly Efficient Hydrogen Evolution.Importance of non-intrinsic platinum dissolution in Pt/C composite fuel cell catalysts.Stability and Activity of Non-Noble-Metal-Based Catalysts Toward the Hydrogen Evolution Reaction.Environmentally Friendly Carbon-Preserving Recovery of Noble Metals From Supported Fuel Cell Catalysts.Kinetically induced irreversibility in electro-oxidation and reduction of Pt surface.Surface oxide growth on platinum electrode in aqueous trifluoromethanesulfonic acid.Nanoscale kinetics of asymmetrical corrosion in core-shell nanoparticles.Heterogeneous catalysis.Coupling of a scanning flow cell with online electrochemical mass spectrometry for screening of reaction selectivity.New Insight into Platinum Dissolution from Nanoparticulate Platinum-Based Electrocatalysts Using Highly Sensitive In Situ Concentration MeasurementsThe influence of chloride impurities on Pt/C fuel cell catalyst corrosionTime Evolution of the Stability and Oxygen Reduction Reaction Activity of PtCu/C Nanoparticles
P2860
Q37135591-09CB9DF9-A095-408A-A23A-FC1797572B6CQ37188283-5B0A434B-E32A-4FA4-884E-673015CC2485Q37363824-53CCB375-C652-4C4F-A495-9B49D08835BEQ37488197-0E68E00D-B0C6-41DC-B17F-17CA76911D9EQ37733201-C3373E15-9B5A-47F3-AF67-A0A9BEE51046Q38095357-5B28D4CB-4565-44E5-9D71-16EEB0C46F96Q38178028-5205CE95-E4EB-4139-8E63-03BDC9405FDCQ38180973-2FE4BE6E-4104-4357-B398-87A24DACEF74Q38191495-01CDCB7B-2738-4A8E-BF2C-E6BAA064FC55Q38194143-EB1D68E4-F4BD-4BF1-A266-4C295599F1B1Q38835912-A62396EE-0BB7-4CC7-BCC2-5019C98466D7Q42396603-3B767BFF-BA47-470E-867A-B95B6310F811Q45900374-71E366C2-21D7-405E-916C-8D8AD7929701Q46567870-F84D5E32-2517-4410-9097-B6C97D854267Q46678010-23F54BF2-EE80-4858-A553-CC0C393DB0B2Q47138701-C27C34FC-FEE4-44DC-BE01-5568947371BCQ47863137-38B89CA2-AC3F-4D16-A41C-7216BE168965Q48005500-658D60CC-8E80-4423-A083-9CE255172738Q50277831-5DE52D34-02D2-40EF-A7F1-C6CCA0EBF5BDQ50913486-68EB75A7-D3B5-4C3C-A355-A5CEFB39AC6CQ51017525-002AE3C3-BBDD-4B25-B4AA-9D70F8D2C366Q51735136-28CB4D06-A718-453B-BC31-CB60C5AFB142Q52869595-82ADA2FD-695D-492A-A78D-ED7CF1D2F753Q53399667-E6868339-C46B-445E-8955-4AA5A4D5B85DQ57907983-70FD1410-278C-4ACC-9CDD-56D4C857C66DQ57907984-0C8BFE2E-526A-4816-9411-63535FDC209AQ57907988-9B70FC22-CC19-4C21-8A2E-0BD7D78502D3
P2860
Dissolution of platinum: limits for the deployment of electrochemical energy conversion?
description
2012 nî lūn-bûn
@nan
2012 թուականի Դեկտեմբերին հրատարակուած գիտական յօդուած
@hyw
2012 թվականի դեկտեմբերին հրատարակված գիտական հոդված
@hy
2012年の論文
@ja
2012年論文
@yue
2012年論文
@zh-hant
2012年論文
@zh-hk
2012年論文
@zh-mo
2012年論文
@zh-tw
2012年论文
@wuu
name
Dissolution of platinum: limits for the deployment of electrochemical energy conversion?
@ast
Dissolution of platinum: limits for the deployment of electrochemical energy conversion?
@en
Dissolution of platinum: limits for the deployment of electrochemical energy conversion?
@nl
type
label
Dissolution of platinum: limits for the deployment of electrochemical energy conversion?
@ast
Dissolution of platinum: limits for the deployment of electrochemical energy conversion?
@en
Dissolution of platinum: limits for the deployment of electrochemical energy conversion?
@nl
prefLabel
Dissolution of platinum: limits for the deployment of electrochemical energy conversion?
@ast
Dissolution of platinum: limits for the deployment of electrochemical energy conversion?
@en
Dissolution of platinum: limits for the deployment of electrochemical energy conversion?
@nl
P2093
P2860
P356
P1476
Dissolution of platinum: limits for the deployment of electrochemical energy conversion?
@en
P2093
Angel A Topalov
Josef C Meier
Karl J J Mayrhofer
Michael Auinger
Sebastian O Klemm
P2860
P304
P356
10.1002/ANIE.201207256
P407
P577
2012-12-07T00:00:00Z