npj 2D Materials and Applications (Apr 2023)

Spin-defect characteristics of single sulfur vacancies in monolayer MoS2

  • A. Hötger,
  • T. Amit,
  • J. Klein,
  • K. Barthelmi,
  • T. Pelini,
  • A. Delhomme,
  • S. Rey,
  • M. Potemski,
  • C. Faugeras,
  • G. Cohen,
  • D. Hernangómez-Pérez,
  • T. Taniguchi,
  • K. Watanabe,
  • C. Kastl,
  • J. J. Finley,
  • S. Refaely-Abramson,
  • A. W. Holleitner,
  • A. V. Stier

DOI
https://doi.org/10.1038/s41699-023-00392-2
Journal volume & issue
Vol. 7, no. 1
pp. 1 – 9

Abstract

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Abstract Single spin-defects in 2D transition-metal dichalcogenides are natural spin-photon interfaces for quantum applications. Here we report high-field magneto-photoluminescence spectroscopy from three emission lines (Q1, Q2, and Q*) of He-ion induced sulfur vacancies in monolayer MoS2. Analysis of the asymmetric PL lineshapes in combination with the diamagnetic shift of Q1 and Q2 yields a consistent picture of localized emitters with a wave function extent of ~3.5 nm. The distinct valley-Zeeman splitting in out-of-plane B-fields and the brightening of dark states through in-plane B-fields necessitates spin-valley selectivity of the defect states and lifted spin-degeneracy at zero field. Comparing our results to ab initio calculations identifies the nature of Q1 and Q2 and suggests that Q* is the emission from a chemically functionalized defect. Analysis of the optical degree of circular polarization reveals that the Fermi level is a parameter that enables the tunability of the emitter. These results show that defects in 2D semiconductors may be utilized for quantum technologies.