about
V2O5 encapsulated MWCNTs in 2D surface architecture: Complete solid-state bendable highly stabilized energy efficient supercapacitor device.Battery-Supercapacitor Hybrid Devices: Recent Progress and Future Prospects.Synthesis of Two-Dimensional Materials for Capacitive Energy Storage.3D TiO2@Ni(OH)2 Core-shell Arrays with Tunable Nanostructure for Hybrid Supercapacitor Application.Probing Structural Evolution and Charge Storage Mechanism of NiO2H x Electrode Materials using In Operando Resonance Raman Spectroscopy.The critical role of point defects in improving the specific capacitance of δ-MnO2 nanosheetsLow-crystalline iron oxide hydroxide nanoparticle anode for high-performance supercapacitors.Synthesis and Characterisation of Reduced Graphene Oxide/Bismuth Composite for Electrodes in Electrochemical Energy Storage Devices.Asymmetric Supercapacitor Electrodes and Devices.Solution-Processed Two-Dimensional Metal Dichalcogenide-Based Nanomaterials for Energy Storage and Conversion.Microsupercapacitors as miniaturized energy-storage components for on-chip electronics.Complex Hollow Nanostructures: Synthesis and Energy-Related Applications.Ionic Liquids for Supercapacitor Applications.NiCo2 S4 Materials for Supercapacitor Applications.Biredox ionic liquids with solid-like redox density in the liquid state for high-energy supercapacitors.Boosting the Supercapacitance of Nitrogen-Doped Carbon by Tuning Surface Functionalities.Mesoporous layered hexagonal platelets of Co3O4 nanoparticles with (111) facets for battery applications: high performance and ultra-high rate capability.Hydrothermal encapsulation of VO2(A) nanorods in amorphous carbon by carbonization of glucose for energy storage devices.Binder-Free Hybrid Titanium-Niobium Oxide/Carbon Nanofiber Mats for Lithium-Ion Battery Electrodes.Three-dimensional porous V2O5 hierarchical spheres as a battery-type electrode for a hybrid supercapacitor with excellent charge storage performance.Ni-Co Binary Hydroxide Nanotubes with Three-Dimensionally Structured Nanoflakes: Synthesis and Application as Cathode Materials for Hybrid Supercapacitors.Thiocyanates as attractive redox-active electrolytes for high-energy and environmentally-friendly electrochemical capacitors.Cyclic voltammetry modeling of proton transport effects on redox charge storage in conductive materials: application to a TiO2 mesoporous film.The influence of surface area, porous structure, and surface state on the supercapacitor performance of titanium oxynitride: implications for a nanostructuring strategy.Hierarchical core-shell CoMn2O4@MnO2 nanoneedle arrays for high-performance supercapacitors.High-performance hybrid carbon nanotube fibers for wearable energy storage.Unifying miscellaneous performance criteria for a prototype supercapacitor via Co(OH)2 active material and current collector interactions.MOF-Derived Hollow Cage Nix Co3-x O4 and Their Synergy with Graphene for Outstanding Supercapacitors.Nanostructured CuS networks composed of interconnected nanoparticles for asymmetric supercapacitors.General Formation of M(x)Co(3-x)S4 (M=Ni, Mn, Zn) Hollow Tubular Structures for Hybrid Supercapacitors.Core-double shell ZnO/ZnS@Co3O4 heterostructure as high performance pseudocapacitor.In Situ Synthesis of Vertical Standing Nanosized NiO Encapsulated in Graphene as Electrodes for High-Performance Supercapacitors.Intrinsic limitations of atomic layer deposition for pseudocapacitive metal oxides in porous electrochemical capacitor electrodesTransition-metal-based layered double hydroxides tailored for energy conversion and storageBattery-like Supercapacitors from Vertically Aligned Carbon Nanofiber Coated Diamond: Design and DemonstratorOne-pot hydrothermal synthesis of novel NiCoO2/reduced graphene oxide composites for supercapacitorsInfluence of carbon substrate on the electrochemical performance of carbon/manganese oxide hybrids in aqueous and organic electrolytesCoating of Vertically Aligned Carbon Nanotubes by a Novel Manganese Oxide Atomic Layer Deposition Process for Binder-Free Hybrid CapacitorsElectrospun Nanomaterials for Supercapacitor Electrodes: Designed Architectures and Electrochemical PerformanceFaradaic deionization of brackish and sea water via pseudocapacitive cation and anion intercalation into few-layered molybdenum disulfide
P2860
Q30840546-44887D3B-2644-4066-B44E-7668CF73B27EQ33914254-C0A30D3C-C735-44A4-A290-135DD5FEE63DQ36038409-CECFB6CD-DC4A-4C00-A141-99F4B33C73B3Q36044161-F983DE36-AB42-43F1-9EF5-453A4714475CQ36182480-F869076A-43E8-4122-8F43-38D223CA18E7Q37672868-B93A7AEE-750B-4EEB-9EE6-4AD3196DB20DQ37690209-1266CD86-8189-420E-AE1E-460C022DD93BQ37717990-8782C6D4-C0E6-4008-B888-947FB03C256AQ38752441-792C17E2-4E20-4FBC-8D61-D31023197EDDQ38882107-EC1D7896-E54E-4283-85A1-8ED70C4277FDQ39000670-0093F71D-F1A4-466E-B919-72F910780EBCQ39090379-CAF4CFA2-15BA-473F-9577-35892684D859Q39339861-6E1056EB-B679-4AFC-A6E1-E5D17530213FQ39382797-2BCDDDA8-19C0-463F-9AC2-2890F4EF82E1Q46453885-1F019DD1-1DA9-475E-95C2-16E543870FE6Q47099202-A05EA8D8-0BF9-4D65-A00B-F20C428214CEQ47194931-ACCF3AFF-A1A7-43D9-8059-0A74570DF736Q47263242-AA123961-6143-4E6A-8EA6-6E4BAD8F3615Q47379004-8EF22445-84F4-4BF9-A39F-F0EF805C93F5Q47417516-062E05DC-0C49-42C0-8E9A-FFF085372DDBQ47956842-49CB9BF6-54E1-45FC-8FCD-8FA9949861AEQ48045814-8CF13CC3-434C-4A21-A51A-CC9C64A4AF6DQ48196209-ACE425E6-75AF-4D57-B3B6-CDB5D7390A6BQ48710810-ACB09F31-7CDD-4A2D-B8FF-7CB731A871C0Q50858109-2FA5FA9B-4457-4626-BC07-A21FC495CDBEQ50859256-40BE9DC3-0DA5-4B4D-AAFE-E4CA615F5AE8Q50958783-F51BA71B-FD86-4B54-8DB0-6E2D6E2E0C53Q51050757-35B68307-975A-443D-9366-3031F17BA908Q51193318-D46272C8-870E-4DE7-8CB8-7257BC8D714BQ51839541-2FF64D4B-C023-4191-A25B-B55CF5D18652Q52870407-C58D6BB7-30D8-4130-A50B-43D609C4705FQ55220223-6037F42F-831C-486D-B606-9858823FDE7FQ57425470-4EFF24CB-AC7B-4C6A-B41C-0431313643C4Q57777572-B812D237-F3F0-4F38-97DD-C9BE1B7A1182Q57958999-B98E0A99-E8E7-4B82-9D8C-BC2F31B241F0Q57960875-DB119ECB-19DB-4680-BF0B-EF212F08B362Q57961121-54362DFE-B59F-4331-A6E9-A85222DFB45EQ58208065-CCDC878D-C27B-4629-B963-2F79CD277EEAQ58208066-6BC1545D-FEE1-4680-A9D4-F7B9855A3DE3Q58422775-BBC5C746-F745-4D52-B870-8399D7E855C8
P2860
description
im Januar 2015 veröffentlichter wissenschaftlicher Artikel
@de
wetenschappelijk artikel
@nl
наукова стаття, опублікована у 2015
@uk
name
To Be or Not To Be Pseudocapacitive?
@en
To Be or Not To Be Pseudocapacitive?
@nl
type
label
To Be or Not To Be Pseudocapacitive?
@en
To Be or Not To Be Pseudocapacitive?
@nl
prefLabel
To Be or Not To Be Pseudocapacitive?
@en
To Be or Not To Be Pseudocapacitive?
@nl
P2093
P356
P1476
To Be or Not To Be Pseudocapacitive?
@en
P2093
Daniel Bélanger
Jeffrey W. Long
Thierry Brousse
P304
A5185-A5189
P356
10.1149/2.0201505JES
P577
2015-01-01T00:00:00Z