Characterizing spin-bath parameters using conventional and time-asymmetric Hahn-echo sequences
Abstract
Spin-bath noise characterization, which is typically performed by multi-pulse control sequences, is essential for understanding most spin dynamics in the solid-state. Here, we theoretically propose a method for extracting the characteristic parameters of a noise source with a known spectrum, using a single modified Hahn-echo sequence. By varying the application time of the pulse, measuring the coherence curves of an addressable spin, and fitting the decay coefficients to a theoretical function derived by us, we extract parameters characterizing the physical nature of the noise. Assuming a Lorentzian noise spectrum, we illustrate this method for extracting the correlation time of a bath of nitrogen paramagnetic impurities in diamond, and its coupling strength to the addressable spin of a nitrogen-vacancy center. Considering a realistic experimental scenario with measurement error, the parameters can be extracted with an accuracy of . The scheme is effective for samples having a natural homogeneous coherence time () up to two orders of magnitude greater than the inhomogeneous coherence time (), and mitigates technical noise when further averaging is irrelevant. Beyond its potential for reducing experiment times by an order-of-magnitude, such single-pulse noise characterization could minimize the effects of long time-scale drifts and accumulating pulse imperfections and numerical errors.
Keywords
Cite
@article{arxiv.1904.01233,
title = {Characterizing spin-bath parameters using conventional and time-asymmetric Hahn-echo sequences},
author = {Demitry Farfurnik and Nir Bar-Gill},
journal= {arXiv preprint arXiv:1904.01233},
year = {2020}
}