Active control of excitonic strong coupling and electroluminescence in electrically driven plasmonic nanocavities

Enhancement and active control of light-matter interactions at the atomic scale is important for developing next-generation nanophotonic and quantum optical devices. Here, we demonstrate electric control of both excitonic strong coupling and electroluminescence by integrating semiconductor monolayer...

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Veröffentlicht in:	arXiv.org 2024-09
Hauptverfasser:	Zheng, Junsheng, Yang, Ruoxue, Krasavin, Alexey V, Wang, Zhenxin, Feng, Yuanjia, Tang, Longhua, Li, Linjun, Guo, Xin, Dai, Daoxin, Zayats, Anatoly V, Tong, Limin, Wang, Pan
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Schlagworte:	Active control Bias Coupling Data processing Electric control Electric fields Electroluminescence Excitation spectra Excitons Light sources Modulation Monolayers Plasmonics Plasmons Quantum efficiency Quantum phenomena Quantum tunnelling
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creator	Zheng, Junsheng Yang, Ruoxue Krasavin, Alexey V Wang, Zhenxin Feng, Yuanjia Tang, Longhua Li, Linjun Guo, Xin Dai, Daoxin Zayats, Anatoly V Tong, Limin Wang, Pan
description	Enhancement and active control of light-matter interactions at the atomic scale is important for developing next-generation nanophotonic and quantum optical devices. Here, we demonstrate electric control of both excitonic strong coupling and electroluminescence by integrating semiconductor monolayers into a nanometer gap of electrically driven nanocube-on-mirror plasmonic nanocavities. Particularly, in a strongly-coupled system of nanocavity plasmons and WSe2 excitons, the ultra-strong electric field generated in the nanocavity gap enables a reversible modulation of the Rabi splitting between ~102 and 80 meV with a bias below 2.5 V. In the quantum tunnelling regime, by injecting carriers into a nanocavity-integrated WS2 monolayer, bias-controlled spectrally tunable electroluminescence from charged or neutral excitons is achieved with an external quantum efficiency reaching ~3.5%. These results underline practical approaches to electric control of atomic-scale light-matter interactions for applications including nanoscale light sources, ultrafast electro-optic modulation, quantum information processing and sensing.
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subjects	Active control Bias Coupling Data processing Electric control Electric fields Electroluminescence Excitation spectra Excitons Light sources Modulation Monolayers Plasmonics Plasmons Quantum efficiency Quantum phenomena Quantum tunnelling
title	Active control of excitonic strong coupling and electroluminescence in electrically driven plasmonic nanocavities
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