about
Doxorubicin-conjugated mesoporous magnetic colloidal nanocrystal clusters stabilized by polysaccharide as a smart anticancer drug vehicle.MnO nanoparticle@mesoporous carbon composites grown on conducting substrates featuring high-performance lithium-ion battery, supercapacitor and sensorOne-step bulk preparation of calcium carbonate nanotubes and its application in anticancer drug delivery.Sub-5 nm porous nanocrystals: interfacial site-directed growth on graphene for efficient biocatalysis.Carbon nanodots featuring efficient FRET for real-time monitoring of drug delivery and two-photon imaging.Three-dimensional WS2 nanosheet networks for H2O2 produced for cell signaling.Direct Superassemblies of Freestanding Metal-Carbon Frameworks Featuring Reversible Crystalline-Phase Transformation for Electrochemical Sodium Storage.Nuclear-Targeted Multifunctional Magnetic Nanoparticles for Photothermal Therapy.Ultralight mesoporous magnetic frameworks by interfacial assembly of Prussian blue nanocubes.Growth of Single-Layered Two-Dimensional Mesoporous Polymer/Carbon Films by Self-Assembly of Monomicelles at the Interfaces of Various Substrates.Incorporation of well-dispersed sub-5-nm graphitic pencil nanodots into ordered mesoporous frameworks.Oriented mesoporous nanopyramids as versatile plasmon-enhanced interfaces.Nanowire arrays restore vision in blind mice.Reversible chemical tuning of charge carriers for enhanced photoelectrochemical conversion and probing of living cells.Branched artificial nanofinger arrays by mesoporous interfacial atomic rearrangement.A flexible ligand-based wavy layered metal-organic framework for lithium-ion storage.Mesoporous Fe2O3-CdS Heterostructures for Real-Time Photoelectrochemical Dynamic Probing of Cu(2+).Solar-Energy-Driven Photoelectrochemical Biosensing Using TiO2 Nanowires.One-dimensional CoS2–MoS2 nano-flakes decorated MoO2 sub-micro-wires for synergistically enhanced hydrogen evolutionSimultaneous etching and doping of TiO2 nanowire arrays for enhanced photoelectrochemical performancePhotoelectrochemical detection of glutathione by IrO2-hemin-TiO2 nanowire arraysNanoparticle Superlattices as Efficient Bifunctional Electrocatalysts for Water SplittingSolar-driven photoelectrochemical probing of nanodot/nanowire/cell interfaceSurface plasmon resonance enhanced real-time photoelectrochemical protein sensing by gold nanoparticle-decorated TiO₂ nanowiresRemediation of heavy metal contaminated soil by asymmetrical alternating current electrochemistryPhotoelectrochemical Conversion from Graphitic C3N4 Quantum Dot Decorated Semiconductor NanowiresDihydroartemisinin-Loaded Magnetic Nanoparticles for Enhanced Chemodynamic TherapyDirect/Alternating Current Electrochemical Method for Removing and Recovering Heavy Metal from Water Using Graphene Oxide ElectrodeThree-Dimensional Hierarchical Porous Nanotubes Derived from Metal-Organic Frameworks for Highly Efficient Overall Water Splitting
P50
Q34295175-8B4A22AC-E383-4DC3-B56D-A64B4E5AED20Q37180176-71DCD319-13A3-4C7D-83C8-F2A258DD4B63Q39393200-78A04EFC-F1F3-49E0-8F60-0B84919F457CQ40963828-3E702FD4-5F37-4F73-8C7B-B2EBD32752F6Q44538146-A8BE6326-84CC-4753-871D-A2683357F202Q46590996-5228DB66-1E54-4C91-A213-5D89AFE96239Q48052392-D554B7FD-3E24-4EFD-8B1F-3F4368136B9DQ48854787-0FCA1299-1CF2-4EFA-87C3-1979D6796D3AQ50225410-A7E15F10-CD14-4240-91E9-49D69E62C537Q50962009-AFA20F54-03CF-45A2-B13A-313B1D25E0E1Q51552904-5E7EA5BA-5934-4645-BF17-971372AC6178Q51738453-147526A4-26ED-40F4-BCA4-6A3D96CBF837Q52365200-4C4526DE-DAAC-46E5-A4A3-92B27E40EFD0Q53059322-7C669E09-AFEC-49E4-B58F-8C6709836800Q53293925-123C8C11-70F7-42CC-92CA-267BDD82A06DQ53324677-AF0798B3-5BFE-476B-9ED4-F41A4271992FQ53469335-F1AE9AC7-7726-4C2A-8DAF-C549A0001E7CQ53510668-81A2D608-D87F-4D48-8B14-3E610361E456Q63499716-7BB78276-A2FA-476D-970E-4B30D96171EDQ85945911-285852C6-A66C-43F5-8FCB-88D116FF2052Q86050445-D56D7A94-4C8A-43D9-86E1-64BA4583E7E1Q86547476-D013E9A0-6D83-4AD1-9940-ABAE24F2F565Q87701647-DDA36E55-C844-45AC-AA7A-3A819501C097Q88050809-45F7F475-E0CD-410B-BCA7-DD8BB0BC324CQ89108472-53B17ECA-E9B7-44C8-B0F7-4B76EC4BFFCDQ89376668-789899B5-A3EA-428A-A864-6A33D69025CEQ90638462-9CDCDAAF-2007-4AB8-A9EF-9825C15895B1Q92220182-59407A11-7276-4386-86B3-0FCB2750F1C3Q92324009-3163CEA9-5D0C-410F-8E3A-1CC3BE520CC4
P50
description
onderzoeker
@nl
researcher ORCID ID = 0000-0002-6351-993X
@en
name
Jing Tang
@ast
Jing Tang
@en
Jing Tang
@es
Jing Tang
@nl
type
label
Jing Tang
@ast
Jing Tang
@en
Jing Tang
@es
Jing Tang
@nl
prefLabel
Jing Tang
@ast
Jing Tang
@en
Jing Tang
@es
Jing Tang
@nl
P106
P31
P496
0000-0002-6351-993X