Cosmic Antiproton Sensitivity for the GAPS Experiment

GAPS Collaboration

Cosmic Antiproton Sensitivity for the GAPS Experiment

GAPS Collaboration

Research output: Contribution to journal › Conference article › peer-review

Abstract

The General Antiparticle Spectrometer (GAPS) experiment is a balloon payload designed to measure low-energy cosmic antinuclei during at least three ∼35-day Antarctic flights, with the first flight planned for December, 2022. With its large geometric acceptance and novel exotic atom-based particle identification method, GAPS will detect ∼1000 antiprotons per flight, producing a precision cosmic antiproton spectrum in the kinetic energy range of 0.03 − 0.23 GeV/n at float altitude (corresponding to 0.085 − 0.30 GeV/n at the top of the atmosphere). With these high statistics in a measurement extending to lower energy than any previous experiment, and with orthogonal sources of systematic uncertainty compared to measurements made using traditional magnetic spectrometer techniques, the GAPS antiproton measurement will be sensitive to physics including dark matter annihilation, primordial black hole evaporation, and cosmic ray propagation. The antiproton measurement will also validate the GAPS exotic atom technique for the antideuteron and antihelium rare-event searches and provide insight into models of cosmic particle attenuation and production in the atmosphere. This contribution demonstrates the GAPS sensitivity to antiprotons using a full instrument simulation, event reconstruction, and solar and atmospheric effects.

Original language	English (US)
Article number	136
Journal	Proceedings of Science
Volume	395
State	Published - Mar 18 2022
Event	37th International Cosmic Ray Conference, ICRC 2021 - Virtual, Berlin, Germany Duration: Jul 12 2021 → Jul 23 2021

All Science Journal Classification (ASJC) codes

General

Cite this

@article{2760ed43d8b2463e8219c6769a044335,

title = "Cosmic Antiproton Sensitivity for the GAPS Experiment",

abstract = "The General Antiparticle Spectrometer (GAPS) experiment is a balloon payload designed to measure low-energy cosmic antinuclei during at least three ∼35-day Antarctic flights, with the first flight planned for December, 2022. With its large geometric acceptance and novel exotic atom-based particle identification method, GAPS will detect ∼1000 antiprotons per flight, producing a precision cosmic antiproton spectrum in the kinetic energy range of 0.03 − 0.23 GeV/n at float altitude (corresponding to 0.085 − 0.30 GeV/n at the top of the atmosphere). With these high statistics in a measurement extending to lower energy than any previous experiment, and with orthogonal sources of systematic uncertainty compared to measurements made using traditional magnetic spectrometer techniques, the GAPS antiproton measurement will be sensitive to physics including dark matter annihilation, primordial black hole evaporation, and cosmic ray propagation. The antiproton measurement will also validate the GAPS exotic atom technique for the antideuteron and antihelium rare-event searches and provide insight into models of cosmic particle attenuation and production in the atmosphere. This contribution demonstrates the GAPS sensitivity to antiprotons using a full instrument simulation, event reconstruction, and solar and atmospheric effects.",

author = "{GAPS Collaboration} and Field Rogers and T. Aramaki and R. Bird and M. Boezio and Boggs, {S. E.} and V. Bonvicini and D. Campana and Craig, {W. W.} and E. Everson and L. Fabris and H. Fuke and F. Gahbauer and I. Garcia and C. Gerrity and Hailey, {C. J.} and T. Hayashi and C. Kato and A. Kawachi and S. Kobayashi and M. Kozai and A. Lenni and A. Lowell and M. Manghisoni and N. Marcelli and B. Mochizuki and Mognet, {S. A.I.} and K. Munakata and R. Munini and Y. Nakagami and J. Olson and Ong, {R. A.} and G. Osteria and K. Perez and S. Quinn and V. Re and E. Riceputi and B. Roach and F. Rogers and Ryan, {J. A.} and N. Saffold and V. Scotti and Y. Shimizu and M. Sonzogni and R. Sparvoli and A. Stoessl and A. Tiberio and E. Vannuccini and {von Doetinchem}, P. and T. Wada and M. Xiao",

note = "Funding Information: This work is supported in the U.S. by NASA APRA grants (NNX17AB44G, NNX17AB45G, NNX17AB46G, and NNX17AB47G), in Japan by JAXA/ISAS Small Science Program FY2017, and in Italy by Istituto Nazionale di Fisica Nucleare (INFN) and the Italian Space Agency through ASI INFN agreement No. 2018-28-HH.0: “Partecipazione italiana al GAPS - General AntiParticle Spectrometer”. F. Rogers is supported by the National Science Foundation (NSF) Graduate Research Fellowship under Grant No. 1122374. P. von Doetinchem received support from the NSF under award PHY-1551980. H. Fuke is supported by JSPS KAKENHI grants (JP17H01136 and JP19H05198) and Mitsubishi Foundation Research Grant 2019-10038. K. Perez and M. Xiao are supported by Heising-Simons award 2018-0766. Y. Shimizu receives support from JSPS KAK-ENHI grant JP20K04002 and Sumitomo Foundation Grant No. 180322. Technical support and advanced computing resources from the University of Hawaii Information Technology Services – Cyberinfrastructure are gratefully acknowledged. This research was done using resources provided by the Open Science Grid [29, 30], which is supported by the NSF award No. 2030508. Publisher Copyright: {\textcopyright} Copyright owned by the author(s) under the terms of the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License (CC BY-NC-ND 4.0).; 37th International Cosmic Ray Conference, ICRC 2021 ; Conference date: 12-07-2021 Through 23-07-2021",

year = "2022",

month = mar,

day = "18",

language = "English (US)",

volume = "395",

journal = "Proceedings of Science",

issn = "1824-8039",

publisher = "Sissa Medialab Srl",

}

TY - JOUR

T1 - Cosmic Antiproton Sensitivity for the GAPS Experiment

AU - GAPS Collaboration

AU - Rogers, Field

AU - Aramaki, T.

AU - Bird, R.

AU - Boezio, M.

AU - Boggs, S. E.

AU - Bonvicini, V.

AU - Campana, D.

AU - Craig, W. W.

AU - Everson, E.

AU - Fabris, L.

AU - Fuke, H.

AU - Gahbauer, F.

AU - Garcia, I.

AU - Gerrity, C.

AU - Hailey, C. J.

AU - Hayashi, T.

AU - Kato, C.

AU - Kawachi, A.

AU - Kobayashi, S.

AU - Kozai, M.

AU - Lenni, A.

AU - Lowell, A.

AU - Manghisoni, M.

AU - Marcelli, N.

AU - Mochizuki, B.

AU - Mognet, S. A.I.

AU - Munakata, K.

AU - Munini, R.

AU - Nakagami, Y.

AU - Olson, J.

AU - Ong, R. A.

AU - Osteria, G.

AU - Perez, K.

AU - Quinn, S.

AU - Re, V.

AU - Riceputi, E.

AU - Roach, B.

AU - Rogers, F.

AU - Ryan, J. A.

AU - Saffold, N.

AU - Scotti, V.

AU - Shimizu, Y.

AU - Sonzogni, M.

AU - Sparvoli, R.

AU - Stoessl, A.

AU - Tiberio, A.

AU - Vannuccini, E.

AU - von Doetinchem, P.

AU - Wada, T.

AU - Xiao, M.

N1 - Funding Information: This work is supported in the U.S. by NASA APRA grants (NNX17AB44G, NNX17AB45G, NNX17AB46G, and NNX17AB47G), in Japan by JAXA/ISAS Small Science Program FY2017, and in Italy by Istituto Nazionale di Fisica Nucleare (INFN) and the Italian Space Agency through ASI INFN agreement No. 2018-28-HH.0: “Partecipazione italiana al GAPS - General AntiParticle Spectrometer”. F. Rogers is supported by the National Science Foundation (NSF) Graduate Research Fellowship under Grant No. 1122374. P. von Doetinchem received support from the NSF under award PHY-1551980. H. Fuke is supported by JSPS KAKENHI grants (JP17H01136 and JP19H05198) and Mitsubishi Foundation Research Grant 2019-10038. K. Perez and M. Xiao are supported by Heising-Simons award 2018-0766. Y. Shimizu receives support from JSPS KAK-ENHI grant JP20K04002 and Sumitomo Foundation Grant No. 180322. Technical support and advanced computing resources from the University of Hawaii Information Technology Services – Cyberinfrastructure are gratefully acknowledged. This research was done using resources provided by the Open Science Grid [29, 30], which is supported by the NSF award No. 2030508. Publisher Copyright: © Copyright owned by the author(s) under the terms of the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License (CC BY-NC-ND 4.0).

PY - 2022/3/18

Y1 - 2022/3/18

N2 - The General Antiparticle Spectrometer (GAPS) experiment is a balloon payload designed to measure low-energy cosmic antinuclei during at least three ∼35-day Antarctic flights, with the first flight planned for December, 2022. With its large geometric acceptance and novel exotic atom-based particle identification method, GAPS will detect ∼1000 antiprotons per flight, producing a precision cosmic antiproton spectrum in the kinetic energy range of 0.03 − 0.23 GeV/n at float altitude (corresponding to 0.085 − 0.30 GeV/n at the top of the atmosphere). With these high statistics in a measurement extending to lower energy than any previous experiment, and with orthogonal sources of systematic uncertainty compared to measurements made using traditional magnetic spectrometer techniques, the GAPS antiproton measurement will be sensitive to physics including dark matter annihilation, primordial black hole evaporation, and cosmic ray propagation. The antiproton measurement will also validate the GAPS exotic atom technique for the antideuteron and antihelium rare-event searches and provide insight into models of cosmic particle attenuation and production in the atmosphere. This contribution demonstrates the GAPS sensitivity to antiprotons using a full instrument simulation, event reconstruction, and solar and atmospheric effects.

AB - The General Antiparticle Spectrometer (GAPS) experiment is a balloon payload designed to measure low-energy cosmic antinuclei during at least three ∼35-day Antarctic flights, with the first flight planned for December, 2022. With its large geometric acceptance and novel exotic atom-based particle identification method, GAPS will detect ∼1000 antiprotons per flight, producing a precision cosmic antiproton spectrum in the kinetic energy range of 0.03 − 0.23 GeV/n at float altitude (corresponding to 0.085 − 0.30 GeV/n at the top of the atmosphere). With these high statistics in a measurement extending to lower energy than any previous experiment, and with orthogonal sources of systematic uncertainty compared to measurements made using traditional magnetic spectrometer techniques, the GAPS antiproton measurement will be sensitive to physics including dark matter annihilation, primordial black hole evaporation, and cosmic ray propagation. The antiproton measurement will also validate the GAPS exotic atom technique for the antideuteron and antihelium rare-event searches and provide insight into models of cosmic particle attenuation and production in the atmosphere. This contribution demonstrates the GAPS sensitivity to antiprotons using a full instrument simulation, event reconstruction, and solar and atmospheric effects.

UR - http://www.scopus.com/inward/record.url?scp=85143766300&partnerID=8YFLogxK

UR - http://www.scopus.com/inward/citedby.url?scp=85143766300&partnerID=8YFLogxK

M3 - Conference article

AN - SCOPUS:85143766300

SN - 1824-8039

VL - 395

JO - Proceedings of Science

JF - Proceedings of Science

M1 - 136

T2 - 37th International Cosmic Ray Conference, ICRC 2021

Y2 - 12 July 2021 through 23 July 2021

ER -

Cosmic Antiproton Sensitivity for the GAPS Experiment

Abstract

All Science Journal Classification (ASJC) codes

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