Low-field microwave-free sensors using dipolar spin relaxation of quartet spin states in silicon carbide

TL;DR

This paper explores the dipolar spin relaxation of silicon vacancy qubits in silicon carbide, revealing their potential for developing microwave-free, low-field quantum sensors for biological and medical applications.

Contribution

It provides a comprehensive theoretical analysis of the relaxation dynamics of silicon vacancy centers in SiC, highlighting their suitability for novel low-field quantum sensing.

Findings

Relaxation time $T_1$ depends on magnetic field and spin environment.

Silicon vacancy qubits can operate as microwave-free sensors at low magnetic fields.

Potential applications in biological and medical sensing due to near-infrared emission.

Abstract

Paramagnetic defects and nuclear spins are the major sources of magnetic field-dependent spin relaxation in point defect quantum bits. The detection of related optical signals has led to the development of advanced relaxometry applications with high spatial resolution. The nearly degenerate quartet ground state of the silicon vacancy qubit in silicon carbide (SiC) is of special interest in this respect, as it gives rise to relaxation rate extrema at vanishing magnetic field values and emits in the first near-infra-red transmission window of biological tissues, providing an opportunity for developing novel sensing applications for medicine and biology. However, the relaxation dynamics of the silicon vacancy center in SiC have not yet been fully explored. In this paper, we present results from a comprehensive theoretical investigation of the dipolar spin relaxation of the quartet spin states in various local spin environments. We discuss the underlying physics and quantify the magnetic field and spin bath dependent relaxation time $T_1$. Using these findings we demonstrate that the silicon vacancy qubit in SiC can implement microwave-free low magnetic field quantum sensors of great potential.