Efficient light generation from enhanced inelastic electron tunnelling

Light emission from biased tunnel junctions has recently gained much attention owing to its unique potential to create ultracompact optical sources with terahertz modulation bandwidth 1 – 5 . The emission originates from an inelastic electron tunnelling process in which electronic energy is transfer...

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Veröffentlicht in:	Nature photonics 2018-08, Vol.12 (8), p.485-488
Hauptverfasser:	Qian, Haoliang, Hsu, Su-Wen, Gurunatha, Kargal, Riley, Conor T., Zhao, Jie, Lu, Dylan, Tao, Andrea R., Liu, Zhaowei
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Schlagworte:	639/624/400/1021 639/624/400/1103 Applied and Technical Physics Electron tunneling Letter Light Light emission Light sources Photons Physics Physics and Astronomy Polaritons Quantum Physics Tunnel junctions
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creator	Qian, Haoliang Hsu, Su-Wen Gurunatha, Kargal Riley, Conor T. Zhao, Jie Lu, Dylan Tao, Andrea R. Liu, Zhaowei
description	Light emission from biased tunnel junctions has recently gained much attention owing to its unique potential to create ultracompact optical sources with terahertz modulation bandwidth 1 – 5 . The emission originates from an inelastic electron tunnelling process in which electronic energy is transferred to surface plasmon polaritons and subsequently converted to radiation photons by an optical antenna. Because most of the electrons tunnel elastically, the emission efficiency is typically about 10 −5 –10 −4 . Here, we demonstrate efficient light generation from enhanced inelastic tunnelling using nanocrystals assembled into metal–insulator–metal junctions. The colour of the emitted light is determined by the optical antenna and thus can be tuned by the geometry of the junction structures. The efficiency of far-field free-space light generation reaches ~2%, showing an improvement of two orders of magnitude over previous work 3 , 4 . This brings on-chip ultrafast and ultracompact light sources one step closer to reality. Nanocrystals assembled into metal–insulator–metal junctions can boost the efficiency of light generation from enhanced inelastic tunnelling to ~2%, which is a two orders of magnitude improvement over previous work, paving the way to on-chip ultrafast and ultracompact light sources.
doi_str_mv	10.1038/s41566-018-0216-2
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subjects	639/624/400/1021 639/624/400/1103 Applied and Technical Physics Electron tunneling Letter Light Light emission Light sources Photons Physics Physics and Astronomy Polaritons Quantum Physics Tunnel junctions
title	Efficient light generation from enhanced inelastic electron tunnelling
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