Highly efficent on-chip direct electronic-plasmonic transducers W Du, T Wang, CA NIJHUIS US Patent App. 10/254,479, 2019 | 193* | 2019 |
Highly efficient on-chip direct electronic–plasmonic transducers W Du, T Wang, HS Chu, CA Nijhuis Nature Photonics 11, 623, 2017 | 161 | 2017 |
Highly efficent on-chip direct electronic-plasmonic transducers W Du, T Wang, CA NIJHUIS US Patent App. 15/445,408, 2017 | 161 | 2017 |
On-chip molecular electronic plasmon sources based on self-assembled monolayer tunnel junctions W Du, T Wang, HS Chu, L Wu, R Liu, S Sun, WK Phua, L Wang, ... Nature Photonics 10, 274-280, 2016 | 142 | 2016 |
Phonon-Polaritonic Bowtie Nanoantennas: Controlling Infrared Thermal Radiation at the Nanoscale T Wang, P Li, DN Chigrin, AJ Giles, FJ Bezares, OJ Glembocki, ... ACS Photonics 4 (7), 1753-1760, 2017 | 140 | 2017 |
Optical properties of single infrared resonant circular microcavities for surface phonon polaritons T Wang, P Li, B Hauer, DN Chigrin, T Taubner Nano letters 13 (11), 5051-5055, 2013 | 131 | 2013 |
Excitation of propagating surface plasmons with a scanning tunnelling microscope T Wang, E Boer-Duchemin, Y Zhang, G Comtet, G Dujardin Nanotechnology 22 (17), 175201, 2011 | 126 | 2011 |
Molecular electronic plasmonics T Wang, CA Nijhuis Applied Materials Today 3, 73-86, 2016 | 87 | 2016 |
Comparison of DC and AC Transport in 1.5–7.5 nm Oligophenylene Imine Molecular Wires across Two Junction Platforms: Eutectic Ga–In versus Conducting Probe Atomic Force … CSS Sangeeth, AT Demissie, L Yuan, T Wang, CD Frisbie, CA Nijhuis J. Am. Chem. Soc 138 (23), 7305-7314, 2016 | 74 | 2016 |
Surface enhanced infrared spectroscopy with gold strip gratings T Wang, VH Nguyen, A Buchenauer, U Schnakenberg, T Taubner Optics Express 21 (7), 9005-9010, 2013 | 65 | 2013 |
Graphene-Enhanced Infrared Near-Field Microscopy P Li, T Wang, H Böckmann, T Taubner Nano letters 14 (8), 4400-4405, 2014 | 64 | 2014 |
Highly Confined and Switchable Mid-Infrared Surface Phonon Polariton Resonances of Planar Circular Cavities with a Phase Change Material H Sumikura, T Wang, P Li, AKU Michel, A Heßler, L Jung, M Lewin, ... Nano letters 19 (4), 2549-2554, 2019 | 53 | 2019 |
Large-area, lithography-free, narrow-band and highly directional thermal emitter X Liu, Z Li, Z Wen, M Wu, J Lu, X Chen, X Zhao, T Wang, R Ji, Y Zhang, ... Nanoscale 11 (42), 19742-19750, 2019 | 45 | 2019 |
Electrically-Excited Surface Plasmon Polaritons with Directionality Control Z Dong, HS Chu, D Zhu, W Du, YA Akimov, WP Goh, T Wang, KEJ Goh, ... ACS Photonics 2 (3), 385-391, 2015 | 44 | 2015 |
Edge scattering of surface plasmons excited by scanning tunneling microscopy Y Zhang, E Boer-Duchemin, T Wang, B Rogez, G Comtet, E Le Moal, ... Optics Express 21 (12), 13938-13948, 2013 | 37 | 2013 |
Atomic switches of metallic point contacts by plasmonic heating. W Zhang, H Liu, J Lu, L Ni, Q Li, M Qiu, B Xu, T Lee, Z Zhao, X Wang, ... Light, science & applications 8, 34-34, 2019 | 34 | 2019 |
Directional Excitation of Surface Plasmon Polaritons via Molecular Through-Bond Tunneling across Double-Barrier Tunnel Junctions W Du, Y Han, H Hu, HS Chu, HV Annadata, T Wang, N Tomczak, ... Nano letters, 2019 | 33 | 2019 |
Temporal coherence of propagating surface plasmons T Wang, G Comtet, E Le Moal, G Dujardin, A Drezet, S Huant, ... Optics Letters 39 (23), 6679-6682, 2014 | 27 | 2014 |
Surface-Enhanced Infrared Absorption Spectroscopy Using Charge Transfer Plasmons T Wang, Z Dong, EHH Koay, JKW Yang ACS Photonics, 2019 | 25 | 2019 |
Scattering of electrically excited surface plasmon polaritons by gold nanoparticles studied by optical interferometry with a scanning tunneling microscope T Wang, B Rogez, G Comtet, E Le Moal, W Abidi, H Remita, G Dujardin, ... Physical Review B 92 (4), 045438, 2015 | 24 | 2015 |