Electrically controlled quantum confinement of neutral excitons in 2D semiconductors


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Achieving fully tunable quantum confinement of excitons has been a long-standing goal in optoelectronics and quantum photonics. We demonstrate electrically controlled 1D quantum confinement of neutral excitons by means of a lateral p-i-n junction in a monolayer transition metal dichalcogenide semiconductor. Exciton trapping in the i-region occurs due to the dc Stark effect induced by in-plane electric fields. Remarkably, we observe a new confinement mechanism arising from the repulsive polaronic dressing of excitons by electrons and holes in the surrounding regions. The overall confinement potential leads to quantization of excitonic motion, which manifests in the emergence of multiple spectrally narrow, voltage-dependent resonances in reflectance and photoluminescence measurements. Additionally, the photoluminescence from confined excitonic states exhibits high degree of linear polarization, highlighting the 1D nature of quantum confinement. Electrically tunable quantum confined excitons may provide a scalable platform for arrays of identical single photon sources and constitute building blocks of strongly correlated photonic many-body systems.

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