Noise spectroscopy of a quantum-classical environment with a diamond qubit

Author(s)

Hernández-Gómez, S.; Poggiali, F.; Fabbri, N.; Cappellaro, Paola

Abstract

Knowing a quantum system's environment is critical for its practical use as a quantum device. Qubit sensors can reconstruct the noise spectral density of a classical bath, provided long enough coherence time. Here, we present a protocol that can unravel the characteristics of a more complex environment, comprising both unknown coherently coupled quantum systems, and a larger quantum bath that can be modeled as a classical stochastic field. We exploit the rich environment of a nitrogen-vacancy center in diamond, tuning the environment behavior with a bias magnetic field, to experimentally demonstrate our method. We show how to reconstruct the noise spectral density even when limited by relatively short coherence times, and identify the local spin environment. Importantly, we demonstrate that the reconstructed model can have predictive power, describing the spin qubit dynamics under control sequences not used for noise spectroscopy, a feature critical for building robust quantum devices. At lower bias fields, where the effects of the quantum nature of the bath are more pronounced, we find that more than a single classical noise model are needed to properly describe the spin coherence under different controls, due to the back action of the qubit onto the bath.

Date issued

2018-12

URI

http://hdl.handle.net/1721.1/119832

Department

Massachusetts Institute of Technology. Department of Nuclear Science and Engineering

Journal

Physical Review B

Publisher

American Physical Society

Citation

Hernández-Gómez, S. et al. "Noise spectroscopy of a quantum-classical environment with a diamond qubit." Physical Review B 98, 21 (December 2018: 214307 © 2018 American Physical Society

Version: Final published version

ISSN

2469-9950

2469-9969