Gode Angloher, Mukund Bharadwaj, Mariano Cababie, Ivan Colantoni, Ioan Dafinei, Alessio Ludovico De Santis, Natalia Di Marco, Leonie Einfalt, Francesco Ferella, Fernando Ferroni, Stephan Fichtinger, Adriano Filipponi, Torsten Frank, Markus Friedl, Zengwei Ge, Matti Heikinheimo, Maximilian Hughes, Katri Huitu, Moritz Kellermann, Rituparna Maji, Michele Mancuso, Lorenzo Pagnanini, Federica Petricca, Stefano Pirro, Franz Pröbst, Gianni Profeta, Andrei Puiu, Florian Reindl, Karoline Schäffner, Jochen Schieck, Philipp Schreiner, Christoph Schwertner, Kumrie Shera, Martin Stahlberg, Alex Stendhal, Matthew Stukel, Cesare Tresca, Felix Wagner, Shihai Yue, Vanessa Zema, Yong Zhu
{"title":"Neutrino flux sensitivity to the next galactic core-collapse supernova in COSINUS","authors":"Gode Angloher, Mukund Bharadwaj, Mariano Cababie, Ivan Colantoni, Ioan Dafinei, Alessio Ludovico De Santis, Natalia Di Marco, Leonie Einfalt, Francesco Ferella, Fernando Ferroni, Stephan Fichtinger, Adriano Filipponi, Torsten Frank, Markus Friedl, Zengwei Ge, Matti Heikinheimo, Maximilian Hughes, Katri Huitu, Moritz Kellermann, Rituparna Maji, Michele Mancuso, Lorenzo Pagnanini, Federica Petricca, Stefano Pirro, Franz Pröbst, Gianni Profeta, Andrei Puiu, Florian Reindl, Karoline Schäffner, Jochen Schieck, Philipp Schreiner, Christoph Schwertner, Kumrie Shera, Martin Stahlberg, Alex Stendhal, Matthew Stukel, Cesare Tresca, Felix Wagner, Shihai Yue, Vanessa Zema, Yong Zhu","doi":"arxiv-2409.09109","DOIUrl":null,"url":null,"abstract":"While neutrinos are often treated as a background for many dark matter\nexperiments, these particles offer a new avenue for physics: the detection of\ncore-collapse supernovae. Supernovae are extremely energetic, violent and\ncomplex events that mark the death of massive stars. During their collapse\nstars emit a large number of neutrinos in a short burst. These neutrinos carry\n99\\% of the emitted energy which makes their detection fundamental in\nunderstanding supernovae. This paper illustrates how COSINUS (Cryogenic\nObservatory for SIgnatures seen in Next-generation Underground Searches), a\nsodium iodide (NaI) based dark matter search, will be sensitive to the next\ngalactic core-collapse supernova. The experiment is composed of two separate\ndetectors which will be sensitive to far and nearby supernovae. The inner core\nof the experiment will consist of NaI crystals operating as scintillating\ncalorimeters, mainly sensitive to the Coherent Elastic Scattering of Neutrinos\n(CE$\\nu$NS) against the Na and I nuclei. The low mass of the cryogenic\ndetectors gives the experiment a sensitivity to close supernovae below 1kpc\nwithout pileup. They will see up to hundreds of CE$\\nu$NS events from a\nsupernova happening at 200pc. The crystals reside at the center of a\ncylindrical 230T water tank, instrumented with 30 photomultipliers. This tank\nacts as a passive and active shield able to detect the Cherenkov radiation\ninduced by impinging charged particles from ambient and cosmogenic\nradioactivity. A supernova near the Milky Way Center (10kpc) will be easily\ndetected inducing $\\sim$60 measurable events, and the water tank will have a\n3$\\sigma$ sensitivity to supernovae up to 22kpc, seeing $\\sim$10 events. This\npaper shows how, even without dedicated optimization, modern dark matter\nexperiments will also play their part in the multi-messenger effort to detect\nthe next galactic core-collapse supernova.","PeriodicalId":501068,"journal":{"name":"arXiv - PHYS - Solar and Stellar Astrophysics","volume":null,"pages":null},"PeriodicalIF":0.0000,"publicationDate":"2024-09-13","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"arXiv - PHYS - Solar and Stellar Astrophysics","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/arxiv-2409.09109","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 0
Abstract
While neutrinos are often treated as a background for many dark matter
experiments, these particles offer a new avenue for physics: the detection of
core-collapse supernovae. Supernovae are extremely energetic, violent and
complex events that mark the death of massive stars. During their collapse
stars emit a large number of neutrinos in a short burst. These neutrinos carry
99\% of the emitted energy which makes their detection fundamental in
understanding supernovae. This paper illustrates how COSINUS (Cryogenic
Observatory for SIgnatures seen in Next-generation Underground Searches), a
sodium iodide (NaI) based dark matter search, will be sensitive to the next
galactic core-collapse supernova. The experiment is composed of two separate
detectors which will be sensitive to far and nearby supernovae. The inner core
of the experiment will consist of NaI crystals operating as scintillating
calorimeters, mainly sensitive to the Coherent Elastic Scattering of Neutrinos
(CE$\nu$NS) against the Na and I nuclei. The low mass of the cryogenic
detectors gives the experiment a sensitivity to close supernovae below 1kpc
without pileup. They will see up to hundreds of CE$\nu$NS events from a
supernova happening at 200pc. The crystals reside at the center of a
cylindrical 230T water tank, instrumented with 30 photomultipliers. This tank
acts as a passive and active shield able to detect the Cherenkov radiation
induced by impinging charged particles from ambient and cosmogenic
radioactivity. A supernova near the Milky Way Center (10kpc) will be easily
detected inducing $\sim$60 measurable events, and the water tank will have a
3$\sigma$ sensitivity to supernovae up to 22kpc, seeing $\sim$10 events. This
paper shows how, even without dedicated optimization, modern dark matter
experiments will also play their part in the multi-messenger effort to detect
the next galactic core-collapse supernova.
虽然中微子通常被视为许多暗物质实验的背景,但这些粒子为物理学提供了一个新的途径:探测核坍缩超新星。超新星是标志着大质量恒星死亡的极度高能、剧烈和复杂的事件。在其坍缩过程中,恒星会在短时间内释放出大量中微子。这些中微子携带了99%的发射能量,这使得探测它们成为了解超新星的基础。本文阐述了基于碘化钠(NaI)的暗物质搜索--COSINUS(下一代地下搜索所见中微子低温观测站)将如何对下一个星系的核心坍缩超新星保持敏感。该实验由两个分离的探测器组成,分别对远处和近处的超新星敏感。实验的内核将由作为闪烁量热计工作的 NaI 晶体组成,主要对中微子对 Na 核和 I 核的相干弹性散射(CE$\nu$NS)敏感。低温探测器的低质量使实验对低于 1kpc 的近距离超新星具有灵敏度,而不会产生堆积。它们将看到来自发生在200pc的超新星的多达数百个CE$\nu$NS事件。晶体位于 230T 圆柱形水箱的中心,上面装有 30 个光电倍增管。这个水箱就像一个被动和主动的屏蔽,能够探测到由环境和宇宙放射性带电粒子撞击引起的切伦科夫辐射。银河系中心(10kpc)附近的超新星将很容易被探测到,从而诱发60个可测量事件,而水箱对高达22kpc的超新星的灵敏度为3个西格玛,能看到10个事件。本文展示了即使没有专门的优化,现代暗物质实验也将如何在探测下一颗银河系核心坍缩超新星的多信使努力中发挥作用。