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

IF 4.2 3区物理与天体物理 Q1 ASTRONOMY & ASTROPHYSICS

Astroparticle Physics Pub Date : 2023-09-01 DOI:10.1016/j.astropartphys.2023.102853

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 , R. Veenhof

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引用次数: 17

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 CF $_{4}$ . Initially, pure CF $_{4}$ 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 CF $_{4}$ 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, 5 $σ$ median discovery significance can be achieved in under one day with either generator.

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MIGDAL实验：测量一个罕见的原子过程以帮助寻找暗物质

我们提出了银河系暗物质探测(Migdal)实验，旨在明确观察和研究由快中子散射引起的所谓的Migdal效应。人们希望利用这一难以捉摸的原子过程来扩大对低质量暗物质的直接搜索实验的范围，但它仍然缺乏实验证实。我们的目标是通过部署一个充满基于CF4的低压气体的光学时间投影室，以低但可计算的概率检测预测的原子电子发射，原子电子发射被认为伴随着核散射。最初，将使用纯CF4，然后在包含其他元素的混合物中使用领先的暗物质搜索技术，包括稀有元素，加上Si和Ge。由气体电子倍增器堆栈生成的高分辨率轨道图像，以及来自闪烁和电离读出的定时信息，将用于该过程中预期的特征事件拓扑的3D重建-两条轨道共享一个共同顶点的安排，其中一个属于米格达尔电子，另一个属于核反冲。两条轨道上不同的能量损失率分布将被用作对背景事件的强大区分工具。在本文中，我们介绍了实验的设计，通过广泛的粒子和轨迹模拟以及信号和背景速率的详细估计。在纯CF4中，我们预计在位于卢瑟福阿普尔顿实验室(英国)的NILE设施中，每个日历日暴露于强烈的D-D (D-T)中子发生器光束下，将观察到8.9(29.3)米格达尔事件。根据我们的名义假设，使用任何一个生成器都可以在一天内实现5σ中位数发现显著性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Astroparticle Physics 地学天文-天文与天体物理

CiteScore

8.00

自引率

2.90%

发文量

审稿时长

79 days

期刊介绍： Astroparticle Physics publishes experimental and theoretical research papers in the interacting fields of Cosmic Ray Physics, Astronomy and Astrophysics, Cosmology and Particle Physics focusing on new developments in the following areas: High-energy cosmic-ray physics and astrophysics; Particle cosmology; Particle astrophysics; Related astrophysics: supernova, AGN, cosmic abundances, dark matter etc.; Gravitational waves; High-energy, VHE and UHE gamma-ray astronomy; High- and low-energy neutrino astronomy; Instrumentation and detector developments related to the above-mentioned fields.