English

Optimizing a Dynamical Decoupling Protocol for Solid-State Electronic Spin Ensembles in Diamond

Quantum Physics 2015-09-02 v3

Abstract

We demonstrate significant improvements of the spin coherence time of a dense ensemble of nitrogen-vacancy (NV) centers in diamond through optimized dynamical decoupling (DD). Cooling the sample down to 7777 K suppresses longitudinal spin relaxation T1T_1 effects and DD microwave pulses are used to increase the transverse coherence time T2T_2 from 0.7\sim 0.7 ms up to 30\sim 30 ms. We extend previous work of single-axis (CPMG) DD towards the preservation of arbitrary spin states. Following a theoretical and experimental characterization of pulse and detuning errors, we compare the performance of various DD protocols. We identify that the optimal control scheme for preserving an arbitrary spin state is a recursive protocol, the concatenated version of the XY8 pulse sequence. The improved spin coherence might have an immediate impact on improvements of the sensitivities of AC magnetometry. Moreover, the protocol can be used on denser diamond samples to increase coherence times up to NV-NV interaction time scales, a major step towards the creation of quantum collective NV spin states.

Keywords

Cite

@article{arxiv.1505.00636,
  title  = {Optimizing a Dynamical Decoupling Protocol for Solid-State Electronic Spin Ensembles in Diamond},
  author = {Demitry Farfurnik and Andrey Jarmola and Linh M. Pham and Zhi-Hui Wang and Viatcheslav V. Dobrovitski and Ronald L. Walsworth and Dmitry Budker and Nir Bar-Gill},
  journal= {arXiv preprint arXiv:1505.00636},
  year   = {2015}
}
R2 v1 2026-06-22T09:27:38.882Z