Entanglement-based dc magnetometry with separated ions
Abstract
We demonstrate sensing of inhomogeneous dc magnetic fields by employing entangled trapped ions, which are shuttled in a segmented Paul trap. As \textit{sensor states}, we use Bell states of the type encoded in two Ca ions stored at different locations. Due to the linear Zeeman effect, the relative phase serves to measure the magnetic field difference between the constituent locations, while common-mode fluctuations are rejected. Consecutive measurements on sensor states encoded in the ground state and in the metastable state are used to separate an ac Zeeman shift from the linear dc Zeeman effect. We measure magnetic field differences over distances of up to , with accuracies of around 300~fT, sensitivities down to , and spatial resolutions down to . For optimizing the information gain while maintaining a high dynamic range, we implement an algorithm for Bayesian frequency estimation.
Keywords
Cite
@article{arxiv.1704.01793,
title = {Entanglement-based dc magnetometry with separated ions},
author = {T. Ruster and H. Kaufmann and M. A. Luda and V. Kaushal and C. T. Schmiegelow and F. Schmidt-Kaler and U. G. Poschinger},
journal= {arXiv preprint arXiv:1704.01793},
year = {2017}
}