Litcius/Paper detail

State-dependent phonon-limited spin relaxation of nitrogen-vacancy centers

Matthew Carl Cambria, Aedan Gardill, Y. Li, Ariel Norambuena, J. R. Maze, Shimon Kolkowitz

2021Physical Review Research21 citationsDOIOpen Access PDF

Abstract

Understanding the limits to the spin coherence of the nitrogen-vacancy (NV) center in diamond is vital to realizing the full potential of this quantum system. We show that relaxation on the |m s = -1 |m s = +1 transition occurs approximately twice as fast as relaxation on the |m s = 0 |m s = 1 transitions under ambient conditions in native NVs in high-purity bulk diamond. The rates we observe are independent of NV concentration over four orders of magnitude, indicating they are limited by spin-phonon interactions. We find that the maximum theoretically achievable coherence time for an NV at 295 K is limited to 6.8(2) ms. Finally, we present a theoretical analysis of our results that suggests Orbach-like relaxation from quasilocalized phonons or contributions due to higher-order terms in the spin-phonon Hamiltonian are the dominant mechanism behind |m s = -1 |m s = +1 relaxation, motivating future measurements of the temperature dependence of this relaxation rate.

Topics & Concepts

Vacancy defectPhononCondensed matter physicsRelaxation (psychology)State (computer science)NitrogenSpin (aerodynamics)PhysicsMaterials scienceQuantum mechanicsMedicineMathematicsThermodynamicsAlgorithmInternal medicineDiamond and Carbon-based Materials ResearchSemiconductor materials and devicesHigh-pressure geophysics and materials