Deterministic coupling of site-controlled quantum emitters in monolayer semiconductors to plasmonic nanocavities
Yue Luo, Gabriella D. Shepard, Jenny V. Ardelean, James C. Hone and, Stefan Strauf
TL;DR
This paper presents a deterministic method to enhance quantum emitter performance in 2D materials by coupling them to plasmonic nanocavities at predefined locations, significantly improving emission rates and quantum yields.
Contribution
It introduces a lithographically defined, deterministic coupling technique using metal nanocubes to enhance quantum emitters in monolayer semiconductors, enabling scalable quantum photonic devices.
Findings
Achieved Purcell factors up to 1050.
Enhanced quantum yields from 1% to 15%.
Demonstrated deterministic emitter-cavity coupling in 2D materials.
Abstract
Solid-state single-quantum emitters are a crucial resource for on-chip photonic quantum technologies and require efficient cavity-emitter coupling to realize quantum networks beyond the single-node level. Previous approaches to enhance light-matter interactions rely on forming nanocavities around randomly located quantum dots or color centers but lack spatial control of the quantum emitter itself that is required for scaling. Here we demonstrate a deterministic approach to achieve Purcell-enhancement at lithographically defined locations using the sharp corner of a metal nanocube for both electric field enhancement and to deform a two-dimensional material. For a 3 by 4 array of strain-induced exciton quantum emitters formed into monolayer WSe2 we show spontaneous emission rate enhancement with Purcell-factors (FP) up to FP=1050 (average FP=272), single-photon purification, and…
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