Controlling the Silicon Vacancy in Silicon Carbide via Electric and Magnetic Fields

Daniil Lukin; Melissa Guidry; Shuo Sun; Constantin Dory; Jelena Vuckovic

Controlling the Silicon Vacancy in Silicon Carbide via Electric and Magnetic Fields

ORAL

Abstract

The Silicon Vacancy in Silicon Carbide is an optically-active, spin-3/2 defect with a long spin coherence and potential for integration into large-scale nanophotonic circuits due to its narrow, stable optical transitions and small inhomogenous broadening. We demonstrate the optical transitions of the Silicon Vacancy are widely tunable via electric fields, which may enable multi-emitter scalability. We perform magnetic-field spectroscopy on single defects, and discuss the cavity-assisted spin-initialization protocols enabled by its fine structure.

March 5, 2020, 2:15 PM – March 5, 2020, 2:27 PM

Presenters

Daniil Lukin

Stanford Univ

Authors

Daniil Lukin

Stanford Univ
Melissa Guidry

Stanford Univ
Shuo Sun

Stanford University, Stanford Univ
Constantin Dory

Stanford University, Stanford Univ
Jelena Vuckovic

Stanford Univ, Stanford University, Electrical Engineering, Stanford University