Related papers: Imaging trapped ion structures via fluorescence cross-correlation detection

Imaging trapped ion structures via fluorescence cross-correlation detection

URL: http://arxiv.org/abs/2012.13206v1
Date: Thu, 24 Dec 2020 11:54:41 GMT
Title: Imaging trapped ion structures via fluorescence cross-correlation detection
Authors: Stefan Richter, Sebastian Wolf, Joachim von Zanthier, Ferdinand Schmidt-Kaler
Abstract summary: Cross-correlation signals are recorded from fluorescence photons scattered in free space off a trapped ion structure. The analysis of the signal allows for unambiguously revealing the spatial frequency, as well as the spatial alignment of the ions.
Score: 26.98676199482944
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: Cross-correlation signals are recorded from fluorescence photons scattered in free space off a trapped ion structure. The analysis of the signal allows for unambiguously revealing the spatial frequency, thus the distance, as well as the spatial alignment of the ions. For the case of two ions we obtain from the cross-correlations a spatial frequency $f_\text{spatial}=1490 \pm 2_{stat.}\pm 8_{syst.}\,\text{rad}^{-1}$, where the statistical uncertainty improves with the integrated number of correlation events as $N^{-0.51\pm0.06}$. We independently determine the spatial frequency to be $1494\pm 11\,\text{rad}^{-1}$, proving excellent agreement. Expanding our method to the case of three ions, we demonstrate its functionality for two-dimensional arrays of emitters of indistinguishable photons, serving as a model system to yield structural information where direct imaging techniques fail.

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