Nature Communications (Jul 2024)

Confinement of excited states in two-dimensional, in-plane, quantum heterostructures

  • Gwangwoo Kim,
  • Benjamin Huet,
  • Christopher E. Stevens,
  • Kiyoung Jo,
  • Jeng-Yuan Tsai,
  • Saiphaneendra Bachu,
  • Meghan Leger,
  • Seunguk Song,
  • Mahfujur Rahaman,
  • Kyung Yeol Ma,
  • Nicholas R. Glavin,
  • Hyeon Suk Shin,
  • Nasim Alem,
  • Qimin Yan,
  • Joshua R. Hendrickson,
  • Joan M. Redwing,
  • Deep Jariwala

DOI
https://doi.org/10.1038/s41467-024-50653-x
Journal volume & issue
Vol. 15, no. 1
pp. 1 – 10

Abstract

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Abstract Two-dimensional (2D) semiconductors are promising candidates for optoelectronic application and quantum information processes due to their inherent out-of-plane 2D confinement. In addition, they offer the possibility of achieving low-dimensional in-plane exciton confinement, similar to zero-dimensional quantum dots, with intriguing optical and electronic properties via strain or composition engineering. However, realizing such laterally confined 2D monolayers and systematically controlling size-dependent optical properties remain significant challenges. Here, we report the observation of lateral confinement of excitons in epitaxially grown in-plane MoSe2 quantum dots (~15-60 nm wide) inside a continuous matrix of WSe2 monolayer film via a sequential epitaxial growth process. Various optical spectroscopy techniques reveal the size-dependent exciton confinement in the MoSe2 monolayer quantum dots with exciton blue shift (12-40 meV) at a low temperature as compared to continuous monolayer MoSe2. Finally, single-photon emission (g2(0) ~ 0.4) was also observed from the smallest dots at 1.6 K. Our study opens the door to compositionally engineered, tunable, in-plane quantum light sources in 2D semiconductors.