The MIGDAL experiment: Measuring a rare atomic process to aid the search for dark matter

H.M. Araújo; S.N. Balashov; J.E. Borg; F.M. Brunbauer; C. Cazzaniga; C.D. Frost; F. Garcia; A.C. Kaboth; M. Kastriotou; I. Katsioulas; A. Khazov; H. Kraus; V.A. Kudryavtsev; S. Lilley; A. Lindote; D. Loomba; M.I. Lopes; E. Lopez Asamar; P. Luna Dapica; P.A. Majewski; T. Marley; C. Mccabe; A.F. Mills; M. Nakhostin; T. Neep; F. Neves; K. Nikolopoulos; E. Oliveri; L. Ropelewski; E. Tilly; V.N. Solovov; T.J. Sumner; J. Tarrant; R. Turnley; M.G.D. Van der grinten; R. Veenhof

doi:10.1016/j.astropartphys.2023.102853

The MIGDAL experiment: Measuring a rare atomic process to aid the search for dark matter

H.M. Araújo^*, S.N. Balashov, J.E. Borg, F.M. Brunbauer, C. Cazzaniga, C.D. Frost, F. Garcia, A.C. Kaboth, M. Kastriotou, I. Katsioulas, A. Khazov, H. Kraus, V.A. Kudryavtsev, S. Lilley, A. Lindote, D. Loomba, M.I. Lopes, E. Lopez Asamar, P. Luna Dapica, P.A. Majewski^*T. Marley, C. Mccabe, A.F. Mills, M. Nakhostin, T. Neep, F. Neves, K. Nikolopoulos, E. Oliveri, L. Ropelewski, E. Tilly, V.N. Solovov, T.J. Sumner, J. Tarrant, R. Turnley, M.G.D. Van der grinten, R. Veenhof

^*Corresponding author for this work

Physics and Astronomy

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Abstract

We present the Migdal In Galactic Dark mAtter expLoration (MIGDAL) experiment aiming at the unambiguous observation and study of the so-called Migdal effect induced by fast-neutron scattering. It is hoped that this elusive atomic process can be exploited to enhance the reach of direct dark matter search experiments to lower masses, but it is still lacking experimental confirmation. Our goal is to detect the predicted atomic electron emission which is thought to accompany nuclear scattering with low, but calculable, probability, by deploying an Optical Time Projection Chamber filled with a low-pressure gas based on CF₄. Initially, pure CF₄ will be used, and then in mixtures containing other elements employed by leading dark matter search technologies — including noble species, plus Si and Ge. High resolution track images generated by a Gas Electron Multiplier stack, together with timing information from scintillation and ionisation readout, will be used for 3D reconstruction of the characteristic event topology expected for this process — an arrangement of two tracks sharing a common vertex, with one belonging to a Migdal electron and the other to a nuclear recoil. Different energy-loss rate distributions along both tracks will be used as a powerful discrimination tool against background events. In this article we present the design of the experiment, informed by extensive particle and track simulations and detailed estimations of signal and background rates. In pure CF₄ we expect to observe 8.9 (29.3) Migdal events per calendar day of exposure to an intense D–D (D–T) neutron generator beam at the NILE facility located at the Rutherford Appleton Laboratory (UK). With our nominal assumptions, 5σ median discovery significance can be achieved in under one day with either generator.

Original language	English
Article number	102853
Number of pages	28
Journal	Astroparticle Physics
Volume	151
Early online date	23 Apr 2023
DOIs	https://doi.org/10.1016/j.astropartphys.2023.102853
Publication status	Published - Sept 2023

Keywords

Dark matter
Direct detection
Neutron scattering
Migdal effect
Gas detectors

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Araújo, H. M., Balashov, S. N., Borg, J. E., Brunbauer, F. M., Cazzaniga, C., Frost, C. D., Garcia, F., Kaboth, A. C., Kastriotou, M., Katsioulas, I., Khazov, A., Kraus, H., Kudryavtsev, V. A., Lilley, S., Lindote, A., Loomba, D., Lopes, M. I., Asamar, E. L., Dapica, P. L., ... Veenhof, R. (2023). The MIGDAL experiment: Measuring a rare atomic process to aid the search for dark matter. Astroparticle Physics, 151, Article 102853. https://doi.org/10.1016/j.astropartphys.2023.102853

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title = "The MIGDAL experiment: Measuring a rare atomic process to aid the search for dark matter",

abstract = "We present the Migdal In Galactic Dark mAtter expLoration (MIGDAL) experiment aiming at the unambiguous observation and study of the so-called Migdal effect induced by fast-neutron scattering. It is hoped that this elusive atomic process can be exploited to enhance the reach of direct dark matter search experiments to lower masses, but it is still lacking experimental confirmation. Our goal is to detect the predicted atomic electron emission which is thought to accompany nuclear scattering with low, but calculable, probability, by deploying an Optical Time Projection Chamber filled with a low-pressure gas based on CF4. Initially, pure CF4 will be used, and then in mixtures containing other elements employed by leading dark matter search technologies — including noble species, plus Si and Ge. High resolution track images generated by a Gas Electron Multiplier stack, together with timing information from scintillation and ionisation readout, will be used for 3D reconstruction of the characteristic event topology expected for this process — an arrangement of two tracks sharing a common vertex, with one belonging to a Migdal electron and the other to a nuclear recoil. Different energy-loss rate distributions along both tracks will be used as a powerful discrimination tool against background events. In this article we present the design of the experiment, informed by extensive particle and track simulations and detailed estimations of signal and background rates. In pure CF4 we expect to observe 8.9 (29.3) Migdal events per calendar day of exposure to an intense D–D (D–T) neutron generator beam at the NILE facility located at the Rutherford Appleton Laboratory (UK). With our nominal assumptions, 5σ median discovery significance can be achieved in under one day with either generator. ",

keywords = "Dark matter, Direct detection, Neutron scattering, Migdal effect, Gas detectors",

author = "H.M. Ara{\'u}jo and S.N. Balashov and J.E. Borg and F.M. Brunbauer and C. Cazzaniga and C.D. Frost and F. Garcia and A.C. Kaboth and M. Kastriotou and I. Katsioulas and A. Khazov and H. Kraus and V.A. Kudryavtsev and S. Lilley and A. Lindote and D. Loomba and M.I. Lopes and Asamar, {E. Lopez} and Dapica, {P. Luna} and P.A. Majewski and T. Marley and C. Mccabe and A.F. Mills and M. Nakhostin and T. Neep and F. Neves and K. Nikolopoulos and E. Oliveri and L. Ropelewski and E. Tilly and V.N. Solovov and T.J. Sumner and J. Tarrant and R. Turnley and {Van der grinten}, M.G.D. and R. Veenhof",

year = "2023",

month = sep,

doi = "10.1016/j.astropartphys.2023.102853",

language = "English",

volume = "151",

journal = "Astroparticle Physics",

issn = "0927-6505",

publisher = "Elsevier",

}

Araújo, HM, Balashov, SN, Borg, JE, Brunbauer, FM, Cazzaniga, C, Frost, CD, Garcia, F, Kaboth, AC, Kastriotou, M, Katsioulas, I, Khazov, A, Kraus, H, Kudryavtsev, VA, Lilley, S, Lindote, A, Loomba, D, Lopes, MI, Asamar, EL, Dapica, PL, Majewski, PA, Marley, T, Mccabe, C, Mills, AF, Nakhostin, M, Neep, T, Neves, F, Nikolopoulos, K, Oliveri, E, Ropelewski, L, Tilly, E, Solovov, VN, Sumner, TJ, Tarrant, J, Turnley, R, Van der grinten, MGD & Veenhof, R 2023, 'The MIGDAL experiment: Measuring a rare atomic process to aid the search for dark matter', Astroparticle Physics, vol. 151, 102853. https://doi.org/10.1016/j.astropartphys.2023.102853

TY - JOUR

T1 - The MIGDAL experiment

T2 - Measuring a rare atomic process to aid the search for dark matter

AU - Araújo, H.M.

AU - Balashov, S.N.

AU - Borg, J.E.

AU - Brunbauer, F.M.

AU - Cazzaniga, C.

AU - Frost, C.D.

AU - Garcia, F.

AU - Kaboth, A.C.

AU - Kastriotou, M.

AU - Katsioulas, I.

AU - Khazov, A.

AU - Kraus, H.

AU - Kudryavtsev, V.A.

AU - Lilley, S.

AU - Lindote, A.

AU - Loomba, D.

AU - Lopes, M.I.

AU - Asamar, E. Lopez

AU - Dapica, P. Luna

AU - Majewski, P.A.

AU - Marley, T.

AU - Mccabe, C.

AU - Mills, A.F.

AU - Nakhostin, M.

AU - Neep, T.

AU - Neves, F.

AU - Nikolopoulos, K.

AU - Oliveri, E.

AU - Ropelewski, L.

AU - Tilly, E.

AU - Solovov, V.N.

AU - Sumner, T.J.

AU - Tarrant, J.

AU - Turnley, R.

AU - Van der grinten, M.G.D.

AU - Veenhof, R.

PY - 2023/9

Y1 - 2023/9

N2 - We present the Migdal In Galactic Dark mAtter expLoration (MIGDAL) experiment aiming at the unambiguous observation and study of the so-called Migdal effect induced by fast-neutron scattering. It is hoped that this elusive atomic process can be exploited to enhance the reach of direct dark matter search experiments to lower masses, but it is still lacking experimental confirmation. Our goal is to detect the predicted atomic electron emission which is thought to accompany nuclear scattering with low, but calculable, probability, by deploying an Optical Time Projection Chamber filled with a low-pressure gas based on CF4. Initially, pure CF4 will be used, and then in mixtures containing other elements employed by leading dark matter search technologies — including noble species, plus Si and Ge. High resolution track images generated by a Gas Electron Multiplier stack, together with timing information from scintillation and ionisation readout, will be used for 3D reconstruction of the characteristic event topology expected for this process — an arrangement of two tracks sharing a common vertex, with one belonging to a Migdal electron and the other to a nuclear recoil. Different energy-loss rate distributions along both tracks will be used as a powerful discrimination tool against background events. In this article we present the design of the experiment, informed by extensive particle and track simulations and detailed estimations of signal and background rates. In pure CF4 we expect to observe 8.9 (29.3) Migdal events per calendar day of exposure to an intense D–D (D–T) neutron generator beam at the NILE facility located at the Rutherford Appleton Laboratory (UK). With our nominal assumptions, 5σ median discovery significance can be achieved in under one day with either generator.

AB - We present the Migdal In Galactic Dark mAtter expLoration (MIGDAL) experiment aiming at the unambiguous observation and study of the so-called Migdal effect induced by fast-neutron scattering. It is hoped that this elusive atomic process can be exploited to enhance the reach of direct dark matter search experiments to lower masses, but it is still lacking experimental confirmation. Our goal is to detect the predicted atomic electron emission which is thought to accompany nuclear scattering with low, but calculable, probability, by deploying an Optical Time Projection Chamber filled with a low-pressure gas based on CF4. Initially, pure CF4 will be used, and then in mixtures containing other elements employed by leading dark matter search technologies — including noble species, plus Si and Ge. High resolution track images generated by a Gas Electron Multiplier stack, together with timing information from scintillation and ionisation readout, will be used for 3D reconstruction of the characteristic event topology expected for this process — an arrangement of two tracks sharing a common vertex, with one belonging to a Migdal electron and the other to a nuclear recoil. Different energy-loss rate distributions along both tracks will be used as a powerful discrimination tool against background events. In this article we present the design of the experiment, informed by extensive particle and track simulations and detailed estimations of signal and background rates. In pure CF4 we expect to observe 8.9 (29.3) Migdal events per calendar day of exposure to an intense D–D (D–T) neutron generator beam at the NILE facility located at the Rutherford Appleton Laboratory (UK). With our nominal assumptions, 5σ median discovery significance can be achieved in under one day with either generator.

KW - Dark matter

KW - Direct detection

KW - Neutron scattering

KW - Migdal effect

KW - Gas detectors

U2 - 10.1016/j.astropartphys.2023.102853

DO - 10.1016/j.astropartphys.2023.102853

M3 - Article

SN - 0927-6505

VL - 151

JO - Astroparticle Physics

JF - Astroparticle Physics

M1 - 102853

ER -

The MIGDAL experiment: Measuring a rare atomic process to aid the search for dark matter

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Keywords

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