about
Ground-State Chemical Reactivity under Vibrational Coupling to the Vacuum Electromagnetic FieldLinear and passive silicon optical isolator.Energy Transfer between Spatially Separated Entangled Molecules.Investigation of size-dependent plasmonic and catalytic properties of metallic nanocrystals enabled by size control with HCl oxidative etching.Supramolecular Self-Assembly in a Sub-micrometer Electrodic Cavity: Fabrication of Heat-Reversible π-Gel Memristor.A nanomesh scaffold for supramolecular nanowire optoelectronic devices.Fast-Response Photonic Device Based on Organic-Crystal Heterojunctions Assembled into a Vertical-Yet-Open Asymmetric Architecture.Manipulating the kinetics of seeded growth for edge-selective metal deposition and the formation of concave au nanocrystals.The role of etching in the formation of Ag nanoplates with straight, curved and wavy edges and comparison of their SERS properties.Manipulation of gold nanorods with dual-optical tweezers for surface plasmon resonance controlSolar energy conversion with tunable plasmonic nanostructures for thermoelectric devicesSelf-Suspended Nanomesh Scaffold for Ultrafast Flexible Photodetectors Based on Organic Semiconducting CrystalsCopper can still be epitaxially deposited on palladium nanocrystals to generate core-shell nanocubes despite their large lattice mismatchFabrication of semiconductor-polymer compound nonlinear photonic crystal slab with highly uniform infiltration based on nano-imprint lithography techniqueSeed-mediated synthesis of single-crystal gold nanospheres with controlled diameters in the range 5-30 nm and their self-assembly upon dilutionNon-Radiative Energy Transfer Mediated by Hybrid Light-Matter StatesNano-Subsidence-Assisted Precise Integration of Patterned Two-Dimensional Materials for High-Performance Photodetector Arrays2D hybrid networks of gold nanoparticles: mechanoresponsive optical humidity sensors
P50
Q28821215-46D5A58C-249C-493F-986D-388C0737790CQ30463503-A69A6D14-4C32-48AE-A418-044774EF247BQ41551611-6A82F7EC-0F6D-4B9C-B0A0-BC86A00D9A90Q47320414-39DED3C5-E0EF-4B30-84F3-1DB0340B2F58Q47755278-09295498-BBA0-413F-AA42-68CE23030AA3Q48144299-0D4516C0-5179-43D5-87F5-1136A7D951D9Q51033387-D49A45BD-0E19-4837-A2C2-155B034CD1FCQ51791490-F8A5DD93-6C9E-4E6B-B216-A3537DF79AD8Q53654992-51B58100-BD8A-41A8-BE6B-FE03D8D38EC7Q56891284-892F4A17-125E-4F78-BF93-B8AFE21593F9Q56993369-D8BEF6A0-1C77-49DA-82E6-BA3C07E795A5Q60159660-20E63929-78DB-4D0B-8002-1C06E36D2538Q83390507-C6634113-E6A7-4191-927E-D4C59CEC10C9Q84413965-02D44237-09EB-4D3F-80D7-968BA3A85332Q86011190-FB8C12CE-7A54-4148-86D1-C18CC8C97CB5Q89173316-F8CDCDC7-2E12-4B92-A7CA-ECC6B802A8D0Q91397429-AC02FF12-5A96-4D34-8EF6-12DD715872E8Q92686110-A5869A7C-FFB5-4A80-A6BA-F49C2A88ADA9
P50
description
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Xiaolan Zhong
@ast
Xiaolan Zhong
@en
Xiaolan Zhong
@es
Xiaolan Zhong
@nl
type
label
Xiaolan Zhong
@ast
Xiaolan Zhong
@en
Xiaolan Zhong
@es
Xiaolan Zhong
@nl
prefLabel
Xiaolan Zhong
@ast
Xiaolan Zhong
@en
Xiaolan Zhong
@es
Xiaolan Zhong
@nl
P106
P31
P496
0000-0003-4819-0416