PRX Quantum (Oct 2023)

Hyperfine Spectroscopy of Isotopically Engineered Group-IV Color Centers in Diamond

  • Isaac B.W. Harris,
  • Cathryn P. Michaels,
  • Kevin C. Chen,
  • Ryan A. Parker,
  • Michael Titze,
  • Jesús Arjona Martínez,
  • Madison Sutula,
  • Ian R. Christen,
  • Alexander M. Stramma,
  • William Roth,
  • Carola M. Purser,
  • Martin Hayhurst Appel,
  • Chao Li,
  • Matthew E. Trusheim,
  • Nicola L. Palmer,
  • Matthew L. Markham,
  • Edward S. Bielejec,
  • Mete Atatüre,
  • Dirk Englund

DOI
https://doi.org/10.1103/PRXQuantum.4.040301
Journal volume & issue
Vol. 4, no. 4
p. 040301

Abstract

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A quantum register coupled to a spin-photon interface is a key component in quantum communication and information processing. Group-IV color centers in diamond (SiV^{−}, GeV^{−}, and SnV^{−}) are promising candidates for this application, comprising an electronic spin with optical transitions coupled to a nuclear spin as the quantum register. However, the creation of a quantum register for these color centers with deterministic and strong coupling to the spin-photon interface remains challenging. Here, we make first-principles predictions of the hyperfine parameters of the group-IV color centers, which we verify experimentally with a comprehensive comparison between the spectra of spin active and spin neutral intrinsic dopant nuclei in single GeV^{−} and SnV^{−} emitters. In line with the theoretical predictions, detailed spectroscopy on large sample sizes reveals that hyperfine coupling causes a splitting of the optical transition of SnV^{−} an order of magnitude larger than the optical line width and provides a magnetic field insensitive transition. This strong coupling provides access to a new regime for quantum registers in diamond color centers, opening avenues for novel spin-photon entanglement and quantum sensing schemes for these well-studied emitters.