Sub-atom shot noise Faraday imaging of ultracold atom clouds

M. A. Kristensen; M. Gajdacz; P. L. Pedersen; C. Klempt; J. F. Sherson; J. J. Arlt; A. J. Hilliard

doi:10.1088/1361-6455/50/3/034004

Sub-atom shot noise Faraday imaging of ultracold atom clouds

M. A. Kristensen
, M. Gajdacz
, P. L. Pedersen
, C. Klempt
, J. F. Sherson
, J. J. Arlt
, A. J. Hilliard

Aarhus University

Research output: Contribution to journal › Article › Research › peer review

Abstract

We demonstrate that a dispersive imaging technique based on the Faraday effect can measure the atom number in a large, ultracold atom cloud with a precision below the atom shot noise level. The minimally destructive character of the technique allows us to take multiple images of the same cloud, which enables sub-atom shot noise measurement precision of the atom number and allows for an in situ determination of the measurement precision. We have developed a noise model that quantitatively describes the noise contributions due to photon shot noise in the detected light and the noise associated with single atom loss. This model contains no free parameters and is calculated through an analysis of the fluctuations in the acquired images. For clouds containing atoms, we achieve a precision more than a factor of two below the atom shot noise level.

Original language	English
Article number	034004
Journal	Journal of Physics B: Atomic, Molecular and Optical Physics
Volume	50
Issue number	3
E-pub ahead of print	17 Jan 2017
DOIs	https://doi.org/10.1088/1361-6455/50/3/034004
Publication status	Published - 14 Feb 2017

Keywords

dispersive imaging
Faraday rotation
non-destructive imaging
sub atom shot noise detection
ultracold atom clouds

ASJC Scopus subject areas

Atomic and Molecular Physics, and Optics
Condensed Matter Physics

Access to Document

10.1088/1361-6455/50/3/034004

http://arxiv.org/pdf/1608.06814Licence: Arxiv nonexclusive-distrib 1.0

Cite this

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title = "Sub-atom shot noise Faraday imaging of ultracold atom clouds",

abstract = "We demonstrate that a dispersive imaging technique based on the Faraday effect can measure the atom number in a large, ultracold atom cloud with a precision below the atom shot noise level. The minimally destructive character of the technique allows us to take multiple images of the same cloud, which enables sub-atom shot noise measurement precision of the atom number and allows for an in situ determination of the measurement precision. We have developed a noise model that quantitatively describes the noise contributions due to photon shot noise in the detected light and the noise associated with single atom loss. This model contains no free parameters and is calculated through an analysis of the fluctuations in the acquired images. For clouds containing atoms, we achieve a precision more than a factor of two below the atom shot noise level.",

keywords = "dispersive imaging, Faraday rotation, non-destructive imaging, sub atom shot noise detection, ultracold atom clouds",

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T1 - Sub-atom shot noise Faraday imaging of ultracold atom clouds

AU - Kristensen, M. A.

AU - Gajdacz, M.

AU - Pedersen, P. L.

AU - Klempt, C.

AU - Sherson, J. F.

AU - Arlt, J. J.

AU - Hilliard, A. J.

PY - 2017/2/14

Y1 - 2017/2/14

N2 - We demonstrate that a dispersive imaging technique based on the Faraday effect can measure the atom number in a large, ultracold atom cloud with a precision below the atom shot noise level. The minimally destructive character of the technique allows us to take multiple images of the same cloud, which enables sub-atom shot noise measurement precision of the atom number and allows for an in situ determination of the measurement precision. We have developed a noise model that quantitatively describes the noise contributions due to photon shot noise in the detected light and the noise associated with single atom loss. This model contains no free parameters and is calculated through an analysis of the fluctuations in the acquired images. For clouds containing atoms, we achieve a precision more than a factor of two below the atom shot noise level.

AB - We demonstrate that a dispersive imaging technique based on the Faraday effect can measure the atom number in a large, ultracold atom cloud with a precision below the atom shot noise level. The minimally destructive character of the technique allows us to take multiple images of the same cloud, which enables sub-atom shot noise measurement precision of the atom number and allows for an in situ determination of the measurement precision. We have developed a noise model that quantitatively describes the noise contributions due to photon shot noise in the detected light and the noise associated with single atom loss. This model contains no free parameters and is calculated through an analysis of the fluctuations in the acquired images. For clouds containing atoms, we achieve a precision more than a factor of two below the atom shot noise level.

KW - dispersive imaging

KW - Faraday rotation

KW - non-destructive imaging

KW - sub atom shot noise detection

KW - ultracold atom clouds

UR - https://www.scopus.com/pages/publications/85010063112

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DO - 10.1088/1361-6455/50/3/034004

M3 - Article

AN - SCOPUS:85010063112

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VL - 50

JO - Journal of Physics B: Atomic, Molecular and Optical Physics

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Sub-atom shot noise Faraday imaging of ultracold atom clouds

Abstract

Keywords

ASJC Scopus subject areas

Access to Document

Other files and links

DQ-mat: Collaborative Research Centre 1227/1, sub-project B01: Entangled neutral atoms for interferometry beyond the standard quantum limit

DQ-mat: Collaborative Research Centre 1227/1: Designed Quantum States of Matter - Generation, Manipulation and Detection for Metrological Applications and Tests of Fundamental Physics

Cite this

Sub-atom shot noise Faraday imaging of ultracold atom clouds

Abstract

Keywords

ASJC Scopus subject areas

Access to Document

Other files and links

Projects

DQ-mat: Collaborative Research Centre 1227/1, sub-project B01: Entangled neutral atoms for interferometry beyond the standard quantum limit

DQ-mat: Collaborative Research Centre 1227/1: Designed Quantum States of Matter - Generation, Manipulation and Detection for Metrological Applications and Tests of Fundamental Physics

Cite this