about
Electrochemically active, crystalline, mesoporous covalent organic frameworks on carbon nanotubes for synergistic lithium-ion battery energy storage.Two-dimensional covalent organic frameworks for carbon dioxide capture through channel-wall functionalizationDesigned synthesis of double-stage two-dimensional covalent organic frameworks.Locking covalent organic frameworks with hydrogen bonds: general and remarkable effects on crystalline structure, physical properties, and photochemical activity.Control of crystallinity and porosity of covalent organic frameworks by managing interlayer interactions based on self-complementary π-electronic force.Radical covalent organic frameworks: a general strategy to immobilize open-accessible polyradicals for high-performance capacitive energy storage.Porous Two-Dimensional Monolayer Metal-Organic Framework Material and Its Use for the Size-Selective Separation of Nanoparticles.Folding Graphene Film Yields High Areal Energy Storage in Lithium-Ion Batteries.Controlling the Thickness of Thermally Expanded Films of Graphene Oxide.A π-electronic covalent organic framework catalyst: π-walls as catalytic beds for Diels-Alder reactions under ambient conditions.Two-dimensional tetrathiafulvalene covalent organic frameworks: towards latticed conductive organic salts.Towards covalent organic frameworks with predesignable and aligned open docking sites.Catalytic covalent organic frameworks via pore surface engineering.Pore surface engineering in covalent organic frameworksConjugated donor-acceptor polymer photocatalysts with electron-output “tentacles” for efficient hydrogen evolutionA squaraine-linked mesoporous covalent organic frameworkRedox-active conjugated microporous polymers: a new organic platform for highly efficient energy storageFreeze-Casting Produces a Graphene Oxide Aerogel with a Radial and Centrosymmetric StructureSupramolecular Alternating Donor-Acceptor Assembly toward Intercalated Covalent Organic FrameworksOrganic Radical-Linked Covalent Triazine Framework with Paramagnetic BehaviorReducing the Exciton Binding Energy of Donor-Acceptor-Based Conjugated Polymers to Promote Charge-Induced ReactionsEnergy-storage covalent organic frameworks: improving performance via engineering polysulfide chains on wallsThermal annealing-induced structural reorganization in polymeric photocatalysts for enhanced hydrogen evolutionSynthesis of Porous Covalent Quinazoline Networks (CQNs) and Their Gas Sorption Properties
P50
Q30389619-5B830FBF-1ED0-4836-81AA-586C8ADE0070Q35753655-F8DE9C32-E26E-4729-8273-ACAC18E06AD6Q36146435-2A2C1311-514E-4CCB-B40F-5C324F0B4111Q42696320-B4EBBB39-22F8-4E12-A592-497ABF39F95DQ46225266-CDFCF36E-ABDB-4B46-B65F-7BA7FCCA96CEQ46738213-F4E14832-9F2E-40ED-818E-BB796D86037BQ47195239-DEFD2C88-27E8-474D-A5C9-DA42B3953EE2Q47709693-9D1A9067-69A9-4C8A-BD4D-9B6F5DE4B14EQ48135341-8A975787-216A-4878-B629-D70A4CBFF4DAQ50973913-AB8C8D19-F4BC-41A7-BA15-2A5DAB6F761CQ51738748-46DCA984-BF1E-4F51-8CC7-23148965F1E9Q51739109-47D8A539-9478-47DB-8EE8-3995971FBEC5Q51765843-9D2C9E83-A5A4-49C5-95F6-8DE2EDFE07A2Q61198283-B65A4071-C8EA-45D4-9F6E-00F84D184E2CQ64218354-6B7BB7C2-08F1-4781-8E9F-3B9F8EF962EAQ86195358-16BA7CDA-1180-4F04-BA3B-FE3A98B8AECDQ87415879-E6D7AE6F-CD6A-419C-9CCF-DF9134C7EEC8Q88662384-44CE234A-3BA0-432E-905F-E5A5373CFFC9Q89613359-2CA38829-B099-4697-A82D-6580A5D5556BQ91594735-4D3D61FE-EE1A-4200-822E-E587C6B12EBEQ92204464-3C30E2B5-45C5-4C4C-83F2-75D45EA48031Q92278186-B69119B6-B9C8-4652-8F1A-AFA24DB71029Q92800573-9DE48334-804E-4D67-A547-DB1425F35031Q93234265-87750090-E923-4D4F-973B-FB8CE1EF1728
P50
description
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Xiong Chen
@ast
Xiong Chen
@en
Xiong Chen
@es
Xiong Chen
@nl
Xiong Chen
@sl
type
label
Xiong Chen
@ast
Xiong Chen
@en
Xiong Chen
@es
Xiong Chen
@nl
Xiong Chen
@sl
prefLabel
Xiong Chen
@ast
Xiong Chen
@en
Xiong Chen
@es
Xiong Chen
@nl
Xiong Chen
@sl
P1053
H-3989-2014
O-8506-2014
P106
P31
P3829
P3835
xiong-chen4
P496
0000-0003-2878-7522