English

Noisy atomic magnetometry in real time

Quantum Physics 2021-12-21 v3 Atomic Physics

Abstract

Continuously monitored atomic spin-ensembles allow, in principle, for real-time sensing of external magnetic fields beyond classical limits. Within the linear-Gaussian regime, thanks to the phenomenon of measurement-induced spin-squeezing, they attain a quantum-enhanced scaling of sensitivity both as a function of time, tt, and the number of atoms involved, NN. In our work, we rigorously study how such conclusions based on Kalman filtering methods change when inevitable imperfections are taken into account: in the form of collective noise, as well as stochastic fluctuations of the field in time. We prove that even an infinitesimal amount of noise disallows the error to be arbitrarily diminished by simply increasing NN, and forces it to eventually follow a classical-like behaviour in tt. However, we also demonstrate that, "thanks" to the presence of noise, in most regimes the model based on a homodyne-like continuous measurement actually achieves the ultimate sensitivity allowed by the decoherence, yielding then the optimal quantum-enhancement. We are able to do so by constructing a noise-induced lower bound on the error that stems from a general method of classically simulating a noisy quantum evolution, during which the stochastic parameter to be estimated -- here, the magnetic field -- is encoded. The method naturally extends to schemes beyond the linear-Gaussian regime, in particular, also to ones involving feedback or active control.

Keywords

Cite

@article{arxiv.2103.12025,
  title  = {Noisy atomic magnetometry in real time},
  author = {Julia Amoros-Binefa and Jan Kolodynski},
  journal= {arXiv preprint arXiv:2103.12025},
  year   = {2021}
}

Comments

27 pages (+16 appendices), 7(+2) figures. Improved summary and conclusions, one extra appendix

R2 v1 2026-06-24T00:26:09.934Z