Mingsong Wang
Mingsong Wang
The University of Texas at Austin, CUNY ASRC
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Zitiert von
Zitiert von
Opto-thermoelectric nanotweezers
L Lin*, M Wang*, X Peng*, EN Lissek, Z Mao, L Scarabelli, E Adkins, ...
Nature photonics 12 (4), 195-201, 2018
Tunable Fano Resonance and Plasmon–Exciton Coupling in Single Au Nanotriangles on Monolayer WS2 at Room Temperature
M Wang, A Krasnok, T Zhang, L Scarabelli, H Liu, Z Wu, LM Liz‐Marzán, ...
Advanced Materials 30 (22), 1705779, 2018
Light-directed reversible assembly of plasmonic nanoparticles using plasmon-enhanced thermophoresis
L Lin, X Peng, M Wang, L Scarabelli, Z Mao, LM Liz-Marzán, MF Becker, ...
ACS nano 10 (10), 9659-9668, 2016
High-performance ultrathin active chiral metamaterials
Z Wu, X Chen, M Wang, J Dong, Y Zheng
ACS nano 12 (5), 5030-5041, 2018
Tunable resonance coupling in single Si nanoparticle–monolayer WS2 structures
S Lepeshov*, M Wang*, A Krasnok, O Kotov, T Zhang, H Liu, T Jiang, ...
ACS applied materials & interfaces 10 (19), 16690-16697, 2018
Seedless growth of palladium nanocrystals with tunable structures: from tetrahedra to nanosheets
Y Zhang, M Wang, E Zhu, Y Zheng, Y Huang, X Huang
Nano Letters 15 (11), 7519-7525, 2015
Tailoring light with layered and moiré metasurfaces
G Hu, M Wang, Y Mazor, CW Qiu, A Alù
Trends in Chemistry 3 (5), 342-358, 2021
Plasmofluidics: Merging Light and Fluids at the Micro‐/Nanoscale
M Wang, C Zhao, X Miao, Y Zhao, J Rufo, YJ Liu, TJ Huang, Y Zheng
small 11 (35), 4423-4444, 2015
Photoswitchable Rabi Splitting in Hybrid Plasmon–Waveguide Modes
L Lin*, M Wang*, X Wei, X Peng, C Xie, Y Zheng
Nano Letters 16 (12), 7655-7663, 2016
Spin-orbit-locked hyperbolic polariton vortices carrying reconfigurable topological charges
M Wang*, G Hu*, S Chand, M Cotrufo, Y Abate, K Watanabe, T Taniguchi, ...
eLight 2 (1), 1-11, 2022
Tunable chiral optics in all-solid-phase reconfigurable dielectric nanostructures
J Li*, M Wang*, Z Wu, H Li, G Hu, T Jiang, J Guo, Y Liu, K Yao, Z Chen, ...
Nano letters 21 (2), 973-979, 2020
Molecular-fluorescence enhancement via blue-shifted plasmon-induced resonance energy transfer
M Wang, B Bangalore Rajeeva, L Scarabelli, EP Perillo, AK Dunn, ...
The Journal of Physical Chemistry C 120 (27), 14820-14827, 2016
Optical nanomanipulation on solid substrates via optothermally-gated photon nudging
J Li, Y Liu, L Lin, M Wang, T Jiang, J Guo, H Ding, PS Kollipara, Y Inoue, ...
Nature Communications 10 (1), 5672, 2019
Plasmon–trion and plasmon–exciton resonance energy transfer from a single plasmonic nanoparticle to monolayer MoS 2
M Wang, W Li, L Scarabelli, BB Rajeeva, M Terrones, LM Liz-Marzán, ...
Nanoscale 9 (37), 13947-13955, 2017
Suppressing material loss in the visible and near-infrared range for functional nanophotonics using bandgap engineering
M Wang, A Krasnok, S Lepeshov, G Hu, T Jiang, J Fang, BA Korgel, A Alù, ...
Nature communications 11 (1), 5055, 2020
Near‐Field Characterization of Higher‐Order Topological Photonic States at Optical Frequencies
A Vakulenko*, S Kiriushechkina*, M Wang*, M Li, D Zhirihin, X Ni, ...
Advanced Materials 33 (18), 2004376, 2021
Dark‐Exciton‐Mediated Fano Resonance from a Single Gold Nanostructure on Monolayer WS2 at Room Temperature
M Wang, Z Wu, A Krasnok, T Zhang, M Liu, H Liu, L Scarabelli, J Fang, ...
Small 15 (31), 1900982, 2019
Effects of CuO doping on the electrical properties of 0.98 K0. 5Na0. 5NbO3–0.02 BiScO3 lead-free piezoelectric ceramics
J Liu, J Zhu, X Li, M Wang, X Zhu, J Zhu, D Xiao
Materials Letters 65 (6), 948-950, 2011
BiScO3-modified (K0. 475Na0. 475Li0. 05)(Nb0. 95Sb0. 05) O3 lead-free piezoelectric ceramics
X Li, J Zhu, M Wang, Y Luo, W Shi, L Li, J Zhu, D Xiao
Journal of Alloys and Compounds 499 (1), L1-L4, 2010
Double hysteresis loop induced by defect dipoles in ferroelectric Pb (Zr0. 8Ti0. 2) O3 thin films
Y Pu, J Zhu, X Zhu, Y Luo, M Wang, X Li, J Liu, J Zhu, D Xiao
Journal of Applied Physics 109 (4), 044102-044102-5, 2011
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