about
Separating hydrogen and oxygen evolution in alkaline water electrolysis using nickel hydroxideA Self-Healing Aqueous Lithium-Ion Battery.Nano active materials for lithium-ion batteries.Electrochemical capacitors: mechanism, materials, systems, characterization and applications.Re-building Daniell cell with a Li-ion exchange filmEnvironmentally-friendly aqueous Li (or Na)-ion battery with fast electrode kinetics and super-long life.Flowerlike vanadium sesquioxide: solvothermal preparation and electrochemical properties.Li-O₂ batteries: an agent for change.Recent progress in supercapacitors: from materials design to system construction.Twisted aligned carbon nanotube/silicon composite fiber anode for flexible wire-shaped lithium-ion battery.Carbon Quantum Dot-Induced MnO2 Nanowire Formation and Construction of a Binder-Free Flexible Membrane with Excellent Superhydrophilicity and Enhanced Supercapacitor Performance.A Long-Life Lithium-Air Battery in Ambient Air with a Polymer Electrolyte Containing a Redox Mediator.Decoupling Hydrogen and Oxygen Production in Acidic Water Electrolysis Using Polytriphenylamine-based Battery Electrode.A clean and membrane-free chlor-alkali process with decoupled Cl2 and H2/NaOH production.TiP2O7 and Expanded Graphite Nanocomposite as Anode Material for Aqueous Lithium-Ion Batteries.A Simple Prelithiation Strategy To Build a High-Rate and Long-Life Lithium-Ion Battery with Improved Low-Temperature Performance.Double-Nanocarbon Synergistically Modified Na3V2(PO4)3: An Advanced Cathode for High-Rate and Long-Life Sodium-Ion Batteries.Flexible, Stretchable, and Rechargeable Fiber-Shaped Zinc-Air Battery Based on Cross-Stacked Carbon Nanotube Sheets.Realizing both high energy and high power densities by twisting three carbon-nanotube-based hybrid fibers.Integrating Desalination and Energy Storage using a Saltwater-based Hybrid Sodium-ion Supercapacitor.Ultrasmall TiO2-Coated Reduced Graphene Oxide Composite as a High-Rate and Long-Cycle-Life Anode Material for Sodium-Ion Batteries.Flexible Aqueous Lithium-Ion Battery with High Safety and Large Volumetric Energy Density.Elastic and wearable wire-shaped lithium-ion battery with high electrochemical performance.All-Organic Rechargeable Battery with Reversibility Supported by "Water-in-Salt" Electrolyte.Synthesis of triaxial LiFePO4 nanowire with a VGCF core column and a carbon shell through the electrospinning method.A Li-air fuel cell with recycle aqueous electrolyte for improved stabilityA lithium-air battery with a potential to continuously reduce O2 from air for delivering energyAn Environmentally Friendly and Flexible Aqueous Zinc Battery Using an Organic CathodeHypophosphites as Eco-Compatible Fuels for Membrane-Free Direct Liquid Fuel CellsAqueous Mg-Ion Battery Based on Polyimide Anode and Prussian Blue CathodeGraphene-Supported Nitrogen and Boron Rich Carbon Layer for Improved Performance of Lithium-Sulfur Batteries Due to Enhanced Chemisorption of Lithium PolysulfidesFlexible Li-air battery in Ambient Air with an In-Situ Formed Gel ElectrolyteMetal-Organic Frameworks as Cathode Materials for Li-O2BatteriesBlack Phosphorus Stabilizing NaTiO/C Each Other with an Improved Electrochemical Property for Sodium-Ion StorageEfficient solar-driven electrocatalytic CO reduction in a redox-medium-assisted systemPolyaniline-intercalated manganese dioxide nanolayers as a high-performance cathode material for an aqueous zinc-ion batteryDual Lithiophilic Structure for Uniform Li DepositionA novel rechargeable Li-AgO battery with hybrid electrolytesControllable hydrogen generation from waterA lithium-air fuel cell using copper to catalyze oxygen-reduction based on copper-corrosion mechanism
P50
Q27314990-18484862-12DB-42ED-BF2F-04B3D499AD02Q36161242-90A91ABD-2034-4A50-B431-5CBBE4283ABCQ37785788-C511D0D1-6C51-4A56-BABA-4236386071E6Q38933066-E94112A9-F657-44C5-948D-8791496D29A4Q41900871-5C049277-6F8C-4372-9107-0C840FC02DD2Q42186386-74C2E8A8-4651-46B0-B3A7-ADB978D3ACA0Q42915323-DFE7D4B8-93CC-45F6-BBC1-031A652CDD7BQ43605419-A1BDD5C6-5E84-44E7-B486-22D08685A601Q44444409-D7CBD271-2AA9-421D-BE4F-E3A8238EA1C4Q46557279-DDFA8CB6-FB7F-4AD0-80A7-FE77813BC02CQ47408584-4C1713C0-5799-49EF-B37E-2F63CC166821Q47575377-CCD9CDD7-38AA-4324-B97B-73BD5CAF9A1EQ47694663-C3EA0FC0-6220-4F68-BB4E-B79B4E549D46Q48043047-64A84EC5-4900-4C4B-AE24-42002CA1C3C9Q48047000-37E294D6-991F-42A4-8B41-74EB9FA08152Q48049048-35850434-A970-43B4-9E96-B8BE4888249AQ51306099-73A81DBA-8CEC-4746-8BA5-8F05D5ABE059Q51666633-62D1C9CB-3256-40AD-8F1D-050A8582488FQ51725943-F943CFDF-3527-4550-977E-E6D45F3B5370Q52587767-70C6DE60-3275-4501-ACF4-C26FA850227BQ52594373-CE46C994-161F-414C-9BFD-BBD611A481F0Q53103877-68515C40-7C8D-46B0-BA5F-FC1B5A4B892CQ53533427-19E90075-19BB-4BD7-AA50-CBFDA306B7B4Q53582793-E98AF9BB-080E-421D-B107-4F659E11D91BQ54606530-449301FE-4113-46A4-A284-D115D8CBDBDDQ55981377-214D29FC-8123-4A32-8B73-84C2340A2164Q55981378-7BE63E63-CA6C-4EE5-9D60-3DEF6E2095F9Q57161541-5E537016-3C16-42D9-9952-FCFFC55DC1F1Q57175206-D79A5446-D5C6-438B-B159-E036A755A27EQ57401863-9ECF0BED-F86E-4A34-B78A-0AE82B469C70Q57401890-1D2C6F98-AB01-467A-829F-FFBF5EE4A21BQ57461112-9507C333-58A9-4103-9965-CEDEAF5A74DCQ57862106-1D3BA955-30FE-4006-880B-22A1AA2B99D1Q58580802-A07CA24A-DC14-44A3-913D-0489C3F0A21EQ59326812-0AF09FD5-CD4B-431F-9ABA-073978E8C7C1Q61135568-8ACADE5F-F717-41C1-B969-5472008F9973Q62107462-B037CA6F-C06A-4401-B541-239C553B7805Q83176344-FDC80503-9B6B-4EAE-B7D4-7C13FB48FACCQ84136214-CD8BD63A-653A-4775-ABE3-4A7CD3F28DBEQ84612591-67BE5DAB-D620-4EFC-8FD3-982FEA76C175
P50
description
researcher
@en
հետազոտող
@hy
name
Yonggang Wang
@ast
Yonggang Wang
@en
Yonggang Wang
@es
Yonggang Wang
@nl
Yonggang Wang
@sl
type
label
Yonggang Wang
@ast
Yonggang Wang
@en
Yonggang Wang
@es
Yonggang Wang
@nl
Yonggang Wang
@sl
prefLabel
Yonggang Wang
@ast
Yonggang Wang
@en
Yonggang Wang
@es
Yonggang Wang
@nl
Yonggang Wang
@sl
P1053
K-4767-2017
P106
P31
P3829
P496
0000-0002-2447-4679