Abstract
Scalable spin-to-photon interfaces require quantum emitters with strong optical-transition dipole moment and low coupling to phonons and stray electric fields. It is known that particularly for coupling to stray electric fields, these conditions can be simultaneously satisfied for emitters that show inversion symmetry. Here, we show that inversion symmetry is not a prerequisite criterion for a spectrally stable quantum emitter. We find that identical electron density in ground and excited states can eliminate the coupling to the stray electric fields. Further, a strong optical-transition dipole moment is achieved in systems with altering sign of the ground and excited wave functions. We use density-functional perturbation theory to investigate an optical center that lacks inversion symmetry. Our results show that this system close to ideally satisfies the criteria for an ideal quantum emitter. Our study opens an additional rationale in seeking promising materials and point defects towards the realization of robust spin-to-photon interfaces.
- Received 14 December 2018
- Revised 26 January 2019
- Corrected 15 October 2020
DOI:https://doi.org/10.1103/PhysRevApplied.11.044022
© 2019 American Physical Society
Physics Subject Headings (PhySH)
Corrections
15 October 2020
Correction: The omission of a support statement in the Acknowledgments has been fixed.