about
Novel approach of processing electrical bioimpedance data using differential impedance analysis.What Do Laser-Induced Transient Techniques Reveal for Batteries? Na- and K-Intercalation from Aqueous Electrolytes as an Example.Exploring the interfaces between metal electrodes and aqueous electrolytes with electrochemical impedance spectroscopy.Techniques and methodologies in modern electrocatalysis: evaluation of activity, selectivity and stability of catalytic materials.Electrodeposited Na2VOx[Fe(CN)6] films As a Cathode Material for Aqueous Na-Ion Batteries.Elucidating the activity of stepped Pt single crystals for oxygen reduction.Theoretical design and experimental implementation of Ag/Au electrodes for the electrochemical reduction of nitrate.Why conclusions from platinum model surfaces do not necessarily lead to enhanced nanoparticle catalysts for the oxygen reduction reaction.A versatile electrochemical cell for the preparation and characterisation of model electrocatalytic systems.Synergistically Enhanced Electrochemical Performance of Hierarchical MoS2/TiNb2O7 Hetero-nanostructures as Anode Materials for Li-Ion Batteries.Influence of the Nature of the Alkali Metal Cations on the Electrical Double-Layer Capacitance of Model Pt(111) and Au(111) Electrodes.Enabling generalized coordination numbers to describe strain effects.A Comprehensive Physical Impedance Model of Polymer Electrolyte Fuel Cell Cathodes in Oxygen-free Atmosphere.Local visualization of catalytic activity at gas evolving electrodes using frequency-dependent scanning electrochemical microscopyDesign of an Active Site towards Optimal Electrocatalysis: Overlayers, Surface Alloys and Near-Surface Alloys of Cu/Pt(111)Understanding the electrocatalysis of oxygen reduction on platinum and its alloysMultiparametric Characterization of Nonelectroactive Self-Assembled Monolayers During Their FormationLocalized electrochemical impedance spectroscopy: visualization of spatial distributions of the key parameters describing solid/liquid interfacesNon-covalent interactions in water electrolysis: influence on the activity of Pt(111) and iridium oxide catalysts in acidic mediaMultistage Mechanism of Lithium Intercalation into Graphite Anodes in the Presence of the Solid Electrolyte InterfaceMultiple Potentials of Maximum Entropy for a Na2Co[Fe(CN)6] Battery Electrode Material: Does the Electrolyte Composition Control the Interface?Oxygen Reduction Activities of Strained Platinum Core-Shell Electrocatalysts Predicted by Machine LearningProspects of Value-Added Chemicals and Hydrogen via ElectrolysisOxygen Reduction Reaction: Rapid Prediction of Mass Activity of Nanostructured Platinum ElectrocatalystsTop-Down Synthesis of Nanostructured Platinum-Lanthanide Alloy Oxygen Reduction Reaction Catalysts: Pt xPr/C as an ExampleOptimizing the Size of Platinum Nanoparticles for Enhanced Mass Activity in the Electrochemical Oxygen Reduction ReactionRevealing the nature of active sites in electrocatalysisRevealing Active Sites for Hydrogen Evolution at Pt and Pd Atomic Layers on Au SurfacesUnprecedented High Oxygen Evolution Activity of Electrocatalysts Derived from Surface-Mounted Metal-Organic FrameworksNature of Highly Active Electrocatalytic Sites for the Hydrogen Evolution Reaction at Pt Electrodes in Acidic MediaOxygen Electroreduction at High-Index Pt Electrodes in Alkaline Electrolytes: A Decisive Role of the Alkali Metal CationsChromium(II) Hexacyanoferrate-Based Thin Films as a Material for Aqueous Alkali Metal Cation Batteries
P50
Q30619127-C6D70B7D-4CB3-4A88-9CD9-9D55C55C917BQ36377570-E3C8D109-00C1-49FB-A72B-CAD57EB38058Q38124271-A79857BF-37E6-44A1-A963-E6C984129B2EQ38178028-F0041E5D-68DB-4FB6-AFAD-1385D2D0F35EQ38756756-EEAA7ABD-F17E-4C3F-AFDF-1F0A9F551E27Q41963472-90FFCD31-1519-4758-BC1F-FAC23BFB84EEQ41971467-E8B53918-F2A7-48F8-A6CE-D32E4F7A9001Q42077930-39F12239-542A-41BF-AEB8-155B6941CA2FQ46409152-2D6C9004-214C-4335-B8BA-B9DA5D4D05CBQ48104251-7C3F4DB0-F9A1-40D6-83FD-18FAF3425BC7Q52622575-90A502A6-5643-43B3-B012-E430413A0B54Q53821272-9F65BF47-41F5-4174-9A45-B93217B3E729Q54997597-FF09BCF2-1FF0-4C0B-81D9-12B777ACBE6DQ60467489-51875B70-D9A1-4D6A-95C2-B9B08D4A5B74Q61603066-47522E76-ADEC-4C83-9042-E0382636AA2FQ61603107-4E81CCA1-ECC4-4E7D-BFE5-BD541EDCAD58Q64461729-264DD579-934D-4314-A641-CC2506085AD3Q85918137-193BE43C-5F9A-4EC8-8FE3-8E099F82FEA5Q86030132-0A71AEB9-4F7A-459E-9E41-6F6C0FBE86D6Q88055352-03EDF5CD-7D6D-4B7D-B269-D767E5A5A132Q88969785-130A99F0-ED4D-42F9-90B7-E3ACA76E2273Q89711231-5836F331-1F5F-4FBF-B351-A09CEA81C8B8Q89718023-B8981132-10E6-4A85-8250-4B81F40E426EQ90363674-8072E9DB-2F81-492A-8EBF-5E53DAF7353AQ91001008-CF686A8F-2566-4351-9C0C-52D7F763AC3CQ91730539-D160FCAF-D7EE-4178-91E5-92F1DDEF383DQ92134086-D8B3AEE0-FCC0-4508-9CDE-EDDA30195FECQ92323234-4410AB44-01F0-4C20-BDF4-E537DBD5E9AEQ92476900-5E7B3280-0DA1-41B5-A902-C6EC7A761854Q92926716-5152158F-4EDE-400E-AD9C-7F7392079ABCQ92932662-544E771B-0B95-479D-A517-91A1E89BB2EFQ92936177-9142D75B-1486-4706-9E12-0D8D7B32C169
P50
description
hulumtues
@sq
onderzoeker
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researcher
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հետազոտող
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name
Aliaksandr S. Bandarenka
@ast
Aliaksandr S. Bandarenka
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Aliaksandr S. Bandarenka
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Aliaksandr S. Bandarenka
@nl
Aliaksandr S. Bandarenka
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type
label
Aliaksandr S. Bandarenka
@ast
Aliaksandr S. Bandarenka
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Aliaksandr S. Bandarenka
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Aliaksandr S. Bandarenka
@nl
Aliaksandr S. Bandarenka
@sl
altLabel
Alexander S Bondarenko
@en
prefLabel
Aliaksandr S. Bandarenka
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Aliaksandr S. Bandarenka
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Aliaksandr S. Bandarenka
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Aliaksandr S. Bandarenka
@nl
Aliaksandr S. Bandarenka
@sl
P106
P1153
7102812726
P21
P31
P496
0000-0002-5970-4315