Interplay between dressed and strong-axial-field states in Nitrogen-Vacancy centers for quantum sensing and computation

TL;DR

This paper investigates how different magnetic field configurations affect the quantum states of NV centers in diamond, revealing insights into their coherence properties and potential for enhanced sensing and quantum computing.

Contribution

It provides a comprehensive analysis of the interplay between dressed and strong-axial field states under various magnetic field conditions in NV centers.

Findings

Detection of both dressed and unbalanced strong-axial states in a single FID measurement

Insights into coherence times and magnetic field sensitivity

Potential for improved quantum sensing and computation applications

Abstract

The Nitrogen-Vacancy (NV) center in diamond is an intriguing electronic spin system with applications in quantum radiometry, sensing and computation. In those experiments, a bias magnetic field is commonly applied along the NV symmetry axis to eliminate the triplet ground state manifold's degeneracy (S=1). In this configuration, the eigenvectors of the NV spin's projection along its axis are called strong-axial field states. Conversely, in some experiments a weak magnetic field is applied orthogonal to the NV symmetry axis, leading to eigenstates that are balanced linear superpositions of strong-axial field states, referred to as dressed states. The latter are sensitive to environmental magnetic noise at the second order, allowing to perform magnetic field protected measurements while providing increased coherence times. However, if a small axial magnetic field is added in this regime, the linear superposition of strong-axial field states becomes unbalanced. This paper presents a comprehensive study of Free Induction Decay (FID) measurements performed on a NV center ensemble in the presence of strain and weak orthogonal magnetic field, as a function of a small magnetic field applied along the NV symmetry axis. The simultaneous detection of dressed states and unbalanced superpositions of strong-axial field states in a single FID measurement is shown, gaining insight about coherence time, nuclear spin and the interplay between temperature and magnetic field sensitivity. The discussion concludes by describing how the simultaneous presence of magnetically-sensitive and -insensitive states opens up appealing possibilities for both sensing and quantum computation applications.