Magneto-optical trapping in a near-suface borehole

Jamie Vovrosh; Katie Wilkinson; Sam Hedges; Kieran McGovern; Farzad Hayati; Christopher Carson; Adam Selyem; Jonathan Winch; Ben Stray; Luuk Earl; Maxwell Hamerow; Georgia Wilson; Adam Seedat; Sanaz Roshanmanesh; Kai Bongs; Michael Holynski

doi:10.1371/journal.pone.0288353

Magneto-optical trapping in a near-suface borehole

Jamie Vovrosh, Katie Wilkinson, Sam Hedges, Kieran McGovern, Farzad Hayati, Christopher Carson, Adam Selyem, Jonathan Winch, Ben Stray, Luuk Earl, Maxwell Hamerow, Georgia Wilson, Adam Seedat, Sanaz Roshanmanesh, Kai Bongs, Michael Holynski^*

^*Corresponding author for this work

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

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Abstract

Borehole gravity sensing can be used in a number of applications to measure features around a well, including rock-type change mapping and determination of reservoir porosity. Quantum technology gravity sensors, based on atom interferometry, have the ability to offer increased survey speeds and reduced need for calibration. While surface sensors have been demonstrated in real world environments, significant improvements in robustness and reductions to radial size, weight, and power consumption are required for such devices to be deployed in boreholes. To realise the first step towards the deployment of cold atom-based sensors down boreholes, we demonstrate a borehole-deployable magneto-optical trap, the core package of many cold atom-based systems. The enclosure containing the magneto-optical trap itself had an outer radius of (60 ± 0.1) mm at its widest point and a length of (890 ± 5) mm. This system was used to generate atom clouds at 1 m intervals in a 14 cm wide, 50 m deep borehole, to simulate how in-borehole gravity surveys are performed. During the survey, the system generated, on average, clouds of (3.0 ± 0.1) × 10⁵ ⁸⁷Rb atoms with the standard deviation in atom number across the survey observed to be as low as 8.9 × 10⁴.

Original language	English
Article number	e0288353
Number of pages	13
Journal	PLOS One
Volume	18
Issue number	7
DOIs	https://doi.org/10.1371/journal.pone.0288353
Publication status	Published - 11 Jul 2023

Bibliographical note

Copyright: © 2023 Vovrosh et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

Keywords

Quantum sensing
Atom interferometry
Gravity Sensing
Boreholes
Geophysics

Access to Document

10.1371/journal.pone.0288353Licence: Creative Commons: Attribution (CC BY)

VovroshJ2023MagnetoFinal published version, 1.82 MBLicence: Creative Commons: Attribution (CC BY)

Additional funding allocationfor UK Quantum Technology Hubin UK National Quantum Technology Hub in Sensing and Timing (linked to 1000194, WT694196)
Roberts, C. (Co-Investigator), Singh, Y. (Co-Investigator), Metje, N. (Co-Investigator), Lien, Y.-H. (Co-Investigator), Faramarzi, A. (Co-Investigator), Holynski, M. (Principal Investigator) & Bongs, K. (Researcher)
Engineering & Physical Science Research Council
1/01/23 → 30/11/24
Project: Research Councils
UK National Quantum Technology Hub in Sensing and Timing Partnership Resource Fund
Bongs, K. (Co-Investigator) & Holynski, M. (Principal Investigator)
Engineering & Physical Science Research Council
1/12/19 → 30/11/24
Project: Research Councils
UK National Quantum Technology Hub in Sensing and Timing
Attallah, M. (Co-Investigator), Jones, R. (Co-Investigator), Metje, N. (Co-Investigator), Constantinou, C. (Co-Investigator), Faramarzi, A. (Co-Investigator), Singh, Y. (Co-Investigator), Holynski, M. (Principal Investigator), Bongs, K. (Co-Investigator), Baker, C. (Co-Investigator), Antoniou, M. (Co-Investigator) & Stewart, E. (Co-Investigator)
Engineering & Physical Science Research Council
1/12/19 → 30/11/24
Project: Research Councils
UK Ouantum Technology Hub for Sensors and Metrology - Partnership Resources
Constantinou, C. (Co-Investigator), Attallah, M. (Co-Investigator), Boyer, V. (Co-Investigator), Metje, N. (Co-Investigator), Freise, A. (Co-Investigator) & Bongs, K. (Principal Investigator)
Engineering & Physical Science Research Council
1/12/14 → 30/11/19
Project: Research Councils
UK Quantum Technology Hub for Sensors and Metrology
Constantinou, C. (Co-Investigator), Bongs, K. (Principal Investigator), Freise, A. (Co-Investigator), Metje, N. (Co-Investigator), Attallah, M. (Co-Investigator) & Boyer, V. (Co-Investigator)
Engineering & Physical Science Research Council
1/12/14 → 30/11/19
Project: Research

Cite this

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abstract = "Borehole gravity sensing can be used in a number of applications to measure features around a well, including rock-type change mapping and determination of reservoir porosity. Quantum technology gravity sensors, based on atom interferometry, have the ability to offer increased survey speeds and reduced need for calibration. While surface sensors have been demonstrated in real world environments, significant improvements in robustness and reductions to radial size, weight, and power consumption are required for such devices to be deployed in boreholes. To realise the first step towards the deployment of cold atom-based sensors down boreholes, we demonstrate a borehole-deployable magneto-optical trap, the core package of many cold atom-based systems. The enclosure containing the magneto-optical trap itself had an outer radius of (60 ± 0.1) mm at its widest point and a length of (890 ± 5) mm. This system was used to generate atom clouds at 1 m intervals in a 14 cm wide, 50 m deep borehole, to simulate how in-borehole gravity surveys are performed. During the survey, the system generated, on average, clouds of (3.0 ± 0.1) × 105 87Rb atoms with the standard deviation in atom number across the survey observed to be as low as 8.9 × 104.",

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AU - Carson, Christopher

AU - Selyem, Adam

AU - Winch, Jonathan

AU - Stray, Ben

AU - Earl, Luuk

AU - Hamerow, Maxwell

AU - Wilson, Georgia

AU - Seedat, Adam

AU - Roshanmanesh, Sanaz

AU - Bongs, Kai

AU - Holynski, Michael

N1 - Copyright: © 2023 Vovrosh et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

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N2 - Borehole gravity sensing can be used in a number of applications to measure features around a well, including rock-type change mapping and determination of reservoir porosity. Quantum technology gravity sensors, based on atom interferometry, have the ability to offer increased survey speeds and reduced need for calibration. While surface sensors have been demonstrated in real world environments, significant improvements in robustness and reductions to radial size, weight, and power consumption are required for such devices to be deployed in boreholes. To realise the first step towards the deployment of cold atom-based sensors down boreholes, we demonstrate a borehole-deployable magneto-optical trap, the core package of many cold atom-based systems. The enclosure containing the magneto-optical trap itself had an outer radius of (60 ± 0.1) mm at its widest point and a length of (890 ± 5) mm. This system was used to generate atom clouds at 1 m intervals in a 14 cm wide, 50 m deep borehole, to simulate how in-borehole gravity surveys are performed. During the survey, the system generated, on average, clouds of (3.0 ± 0.1) × 105 87Rb atoms with the standard deviation in atom number across the survey observed to be as low as 8.9 × 104.

AB - Borehole gravity sensing can be used in a number of applications to measure features around a well, including rock-type change mapping and determination of reservoir porosity. Quantum technology gravity sensors, based on atom interferometry, have the ability to offer increased survey speeds and reduced need for calibration. While surface sensors have been demonstrated in real world environments, significant improvements in robustness and reductions to radial size, weight, and power consumption are required for such devices to be deployed in boreholes. To realise the first step towards the deployment of cold atom-based sensors down boreholes, we demonstrate a borehole-deployable magneto-optical trap, the core package of many cold atom-based systems. The enclosure containing the magneto-optical trap itself had an outer radius of (60 ± 0.1) mm at its widest point and a length of (890 ± 5) mm. This system was used to generate atom clouds at 1 m intervals in a 14 cm wide, 50 m deep borehole, to simulate how in-borehole gravity surveys are performed. During the survey, the system generated, on average, clouds of (3.0 ± 0.1) × 105 87Rb atoms with the standard deviation in atom number across the survey observed to be as low as 8.9 × 104.

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Magneto-optical trapping in a near-suface borehole

Abstract

Bibliographical note

Keywords

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Projects

Additional funding allocationfor UK Quantum Technology Hubin UK National Quantum Technology Hub in Sensing and Timing (linked to 1000194, WT694196)

UK National Quantum Technology Hub in Sensing and Timing Partnership Resource Fund

UK National Quantum Technology Hub in Sensing and Timing

UK Ouantum Technology Hub for Sensors and Metrology - Partnership Resources

UK Quantum Technology Hub for Sensors and Metrology

Cite this