Strain coupling of a single exciton to a nano-optomechanical resonator

Optical Materials Express Pub Date : 2024-07-12 DOI:10.1364/ome.533270
M. Lodde, R. Veldhoven, E. Verhagen, Andrea Fiore
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Abstract

We demonstrate coupling of a semiconductor quantum dot (QD) to an optomechanical cavity, mediated by the strain of a nano-mechanical mode. The device comprises an optomechanical photonic crystal nanobeam in GaAs with embedded In(Ga)As QDs. The flexural mechanical mode of the device can be optically driven exploiting the large optomechanical coupling rate of the cavity. The vibrations generate a time-modulated strain field that shifts the quantum dot transition energy. We observe that optical driving of the mechanical mode induces a shift in an excitonic line corresponding to an estimated vacuum strain coupling rate of 214 kHz. Our approach represents an important step towards the use of phonons to couple different on-chip quantum systems.
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单激子与纳米光机械谐振器的应变耦合
我们展示了通过纳米机械模式应变介导的半导体量子点(QD)与光机械腔体的耦合。该装置包括一个嵌入 In(Ga)As QD 的砷化镓光子机械晶体纳米束。该器件的挠曲机械模式可利用空腔的大光机械耦合率进行光驱动。振动会产生时调应变场,从而改变量子点的转变能。我们观察到,对机械模式的光驱动会引起激子线的移动,与估计的 214 kHz 真空应变耦合率相对应。我们的方法是利用声子耦合不同片上量子系统的重要一步。
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Optical Materials Express
Optical Materials Express
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