DarkGEO: a large-scale laser-interferometric axion detector

Joscha Heinze; Alex Gill; Artemiy Dmitriev; Jiří Smetana; Tianliang Yan; Vincent Boyer; Denis Martynov; Hartmut Grote; James Lough; Aldo Ejlli; Guido Müller

doi:10.1088/1367-2630/ad48ac

DarkGEO: a large-scale laser-interferometric axion detector

Joscha Heinze^*, Alex Gill, Artemiy Dmitriev, Jiří Smetana, Tianliang Yan, Vincent Boyer, Denis Martynov, Hartmut Grote, James Lough, Aldo Ejlli, Guido Müller

^*Corresponding author for this work

Physics and Astronomy

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Abstract

Axions and axion-like particles (ALPs) are leading candidates for dark matter. They are well motivated in many extensions of the standard model and supported by astronomical observations. We propose an iterative transformation of the existing facilities of the gravitational-wave detector and technology testbed GEO600, located near Ruthe in Germany, into a kilometre-scale upgrade of the laser-interferometric axion detector LIDA. The final DarkGEO detector could search for coincident signatures of axions and ALPs and significantly surpass the current constraints of both direct searches and astrophysical observations in the measurement band from 10−16 to 10−8eV. We discuss design parameters and sensitivities for the configurations of the different iteration steps as well as technical challenges known from the first LIDA results. The proposed DarkGEO detector will be well suited to probe the mass-coupling parameter space associated with predictions from theoretical models, like grand-unified theories, as well as from astrophysical evidence, like the cosmic infrared background.

Original language	English
Article number	055002
Journal	New Journal of Physics
Volume	26
Issue number	5
DOIs	https://doi.org/10.1088/1367-2630/ad48ac
Publication status	Published - 21 May 2024

Bibliographical note

Acknowledgments
We acknowledge members of the UK Quantum Interferometry collaboration for useful discussions, the support of the Institute for Gravitational Wave Astronomy at the University of Birmingham and STFC Quantum Technology for Fundamental Physics scheme (Grant Nos. ST/T006331/1, ST/T006609/1 and ST/W006375/1). D M is supported by the 2021 Philip Leverhulme Prize.

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10.1088/1367-2630/ad48acLicence: Creative Commons: Attribution (CC BY)

HeinzeJ2024DarkGEOFinal published version, 961 KBLicence: Creative Commons: Attribution (CC BY)

https://iopscience.iop.org/article/10.1088/1367-2630/ad48ac

Quantum-enhanced Interferometry for New Physics: QI-extension proposal
Martynov, D. (Principal Investigator) & Boyer, V. (Co-Investigator)
SCIENCE & TECHNOLOGY FACILITIES COUNCIL
1/09/22 → 31/08/24
Project: Research Councils
Quantum-enhanced interferometry for new physics
Boyer, V. (Co-Investigator), Miao, H. (Co-Investigator) & Martynov, D. (Principal Investigator)
SCIENCE & TECHNOLOGY FACILITIES COUNCIL, Match Equipment - STFC
1/12/20 → 31/03/25
Project: Research Councils

Cite this

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title = "DarkGEO: a large-scale laser-interferometric axion detector",

abstract = "Axions and axion-like particles (ALPs) are leading candidates for dark matter. They are well motivated in many extensions of the standard model and supported by astronomical observations. We propose an iterative transformation of the existing facilities of the gravitational-wave detector and technology testbed GEO600, located near Ruthe in Germany, into a kilometre-scale upgrade of the laser-interferometric axion detector LIDA. The final DarkGEO detector could search for coincident signatures of axions and ALPs and significantly surpass the current constraints of both direct searches and astrophysical observations in the measurement band from 10−16 to 10−8eV. We discuss design parameters and sensitivities for the configurations of the different iteration steps as well as technical challenges known from the first LIDA results. The proposed DarkGEO detector will be well suited to probe the mass-coupling parameter space associated with predictions from theoretical models, like grand-unified theories, as well as from astrophysical evidence, like the cosmic infrared background.",

author = "Joscha Heinze and Alex Gill and Artemiy Dmitriev and Ji{\v r}{\'i} Smetana and Tianliang Yan and Vincent Boyer and Denis Martynov and Hartmut Grote and James Lough and Aldo Ejlli and Guido M{\"u}ller",

note = "Acknowledgments We acknowledge members of the UK Quantum Interferometry collaboration for useful discussions, the support of the Institute for Gravitational Wave Astronomy at the University of Birmingham and STFC Quantum Technology for Fundamental Physics scheme (Grant Nos. ST/T006331/1, ST/T006609/1 and ST/W006375/1). D M is supported by the 2021 Philip Leverhulme Prize.",

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AU - Heinze, Joscha

AU - Gill, Alex

AU - Dmitriev, Artemiy

AU - Smetana, Jiří

AU - Yan, Tianliang

AU - Boyer, Vincent

AU - Martynov, Denis

AU - Grote, Hartmut

AU - Lough, James

AU - Ejlli, Aldo

AU - Müller, Guido

N1 - Acknowledgments We acknowledge members of the UK Quantum Interferometry collaboration for useful discussions, the support of the Institute for Gravitational Wave Astronomy at the University of Birmingham and STFC Quantum Technology for Fundamental Physics scheme (Grant Nos. ST/T006331/1, ST/T006609/1 and ST/W006375/1). D M is supported by the 2021 Philip Leverhulme Prize.

PY - 2024/5/21

Y1 - 2024/5/21

N2 - Axions and axion-like particles (ALPs) are leading candidates for dark matter. They are well motivated in many extensions of the standard model and supported by astronomical observations. We propose an iterative transformation of the existing facilities of the gravitational-wave detector and technology testbed GEO600, located near Ruthe in Germany, into a kilometre-scale upgrade of the laser-interferometric axion detector LIDA. The final DarkGEO detector could search for coincident signatures of axions and ALPs and significantly surpass the current constraints of both direct searches and astrophysical observations in the measurement band from 10−16 to 10−8eV. We discuss design parameters and sensitivities for the configurations of the different iteration steps as well as technical challenges known from the first LIDA results. The proposed DarkGEO detector will be well suited to probe the mass-coupling parameter space associated with predictions from theoretical models, like grand-unified theories, as well as from astrophysical evidence, like the cosmic infrared background.

AB - Axions and axion-like particles (ALPs) are leading candidates for dark matter. They are well motivated in many extensions of the standard model and supported by astronomical observations. We propose an iterative transformation of the existing facilities of the gravitational-wave detector and technology testbed GEO600, located near Ruthe in Germany, into a kilometre-scale upgrade of the laser-interferometric axion detector LIDA. The final DarkGEO detector could search for coincident signatures of axions and ALPs and significantly surpass the current constraints of both direct searches and astrophysical observations in the measurement band from 10−16 to 10−8eV. We discuss design parameters and sensitivities for the configurations of the different iteration steps as well as technical challenges known from the first LIDA results. The proposed DarkGEO detector will be well suited to probe the mass-coupling parameter space associated with predictions from theoretical models, like grand-unified theories, as well as from astrophysical evidence, like the cosmic infrared background.

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DO - 10.1088/1367-2630/ad48ac

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VL - 26

JO - New Journal of Physics

JF - New Journal of Physics

IS - 5

M1 - 055002

ER -

DarkGEO: a large-scale laser-interferometric axion detector

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Bibliographical note

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Quantum-enhanced Interferometry for New Physics: QI-extension proposal

Quantum-enhanced interferometry for new physics

Cite this