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An Indirect Dark Matter Search Using Cosmic-Ray Antiparticles with GAPS

Authors :
Lowell, Alexander
Aramaki, Tsuguo
Bird, Ralph
Boezio, Mirko
Boggs, Steven
Carr, Rachel
Craig, William
von Doetinchem, Philip
Fabris, Lorenzo
Fuke, Hideyuki
Gahbauer, Florian
Gerrity, Cory
Hailey, Charles
Kato, Chihiro
Kawachi, Akiko
Kozai, Masayoshi
Mognet, Isaac
Munakata, Kazuoki
Okazaki, Shun
Ong, Rene
Osteria, Guiseppe
Perez, Kerstin
Quinn, Sean
Re, Valerio
Rogers, Field
Ryan, Jamie
Saffold, Nathan
Shimizu, Yuki
Stoessl, Achim
Yoshida, Atsumasa
Yoshida, Tetsuya
Zampa, Gianluigi
Zweerink, Jeffrey
Publication Year :
2018

Abstract

Experiments aiming to directly detect dark matter (DM) particles have yet to make robust detections, thus underscoring the need for complementary approaches such as searches for new particles at colliders, and indirect DM searches in cosmic-ray spectra. Low energy (< 0.25 GeV/n) cosmic-ray antiparticles such as antideuterons are strong candidates for probing DM models, as the yield of these particles from DM processes can exceed the astrophysical background by more than two orders of magnitude. The General Antiparticle Spectrometer (GAPS), a balloon borne cosmic-ray detector, will perform an ultra-low background measurement of the cosmic antideuteron flux in the regime < 0.25 GeV/n, which will constrain a wide range of DM models. GAPS will also detect approximately 1000 antiprotons in an unexplored energy range throughout one long duration balloon (LDB) flight, which will constrain < 10 GeV DM models and validate the GAPS detection technique. Unlike magnetic spectrometers, GAPS relies on the formation of an exotic atom within the tracker in order to identify antiparticles. The GAPS tracker consists of ten layers of lithium-drifted silicon detectors which record dE/dx deposits from primary and nuclear annihilation product tracks, as well as measure the energy of the exotic atom deexcitation X-rays. A two-layer, plastic scintillator time of flight (TOF) system surrounds the tracker and measures the particle velocity, dE/dx deposits, and provides a fast trigger to the tracker. The nuclear annihilation product multiplicity, deexcitation X-ray energies, TOF, and stopping depth are all used together to discern between antiparticle species. This presentation provided an overview of the GAPS experiment, an update on the construction of the tracker and TOF systems, and a summary of the expected performance of GAPS in light of the upcoming LDB flight from McMurdo Station, Antarctica in 2020.<br />Comment: 4 pages, 3 figures, The 39th International Conference on High Energy Physics (ICHEP2018), Seoul, Korea

Details

Database :
arXiv
Publication Type :
Report
Accession number :
edsarx.1812.04800
Document Type :
Working Paper