GAPS: A Novel Indirect Search for Dark Mater

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GAPS: A Novel Indirect Search for Dark Mater S. A. Isaac Mognet UCLA May 2, 2011

1 Introduction Indirect Detection of Dark Matter Antideuterons as a DM Signature 2 The General Antiparticle Spectrometer Exotic Atoms Antiproton and Antideuteron Identification GAPS Si(Li) Detectors 3 GAPS Balloon Project bgaps Simulation Work GAPS Balloon Flight Prototype GAPS Flight 4 The GAPS Collaboration 5 Conclusions

Indirect Detection of Dark Matter WIMP Dark Matter could decay or self-annihilate (if it is a Majorana fermion) to standard model particles. This could be anywhere DM is concentrated: in the galactic halo, dwarf spheroidal galaxies, the sun, etc. Could search for charged species or γ s. γ s: Promising, see FERMI, VERITAS, etc. Protons, e : Hopeless Antiprotons, e + : Promising, but large backgrounds Antideuterons: Promising, probably small backgrounds

Antideuterons as a DM Signature Antideuterons from DM Antideuterons could be (rarely) produced from DM in the galactic halo, and thus present in cosmic rays. At low energy, antideuterons from DM-DM annihilation could vastly outnumber those produced from normal astrophysical processes (secondary/tertiary).

GAPS: The General Antiparticle Spectrometer Most experiments use magnetic deflection to distinguish antimatter species (HEAT, AMS, PAMELA, BESS, etc). Light antinuclei can form excited exotic atom states with normal matter. Atomic transition x-rays, charged pion multiplicity, and possible other products provide distinct signature for antinuclei.

Antiproton and Antideuteron Identification Time-of-Flight Identify charge of primary. Measure particle β. Veto heavy cosmic rays/showers. Target/Tracker/x-ray Detector Slow down antiparticles and form exotic atoms. Measure x-ray energies. Track annihilation products. Figure: GAPS with Si target material. Exotic atom technique successfully tested in 2004 KEK test beam. S. A. Isaac Mognet GAPS: A Novel Indirect Search for Dark Mater

GAPS Si(Li) Detectors Lithium drifted silicon provides: Both degrader, target and detector. Excellent x-ray energy resolution ( 3keV ). Tracking of primary particle. Tracking of annihilation products. In-house effort to produce detectors in quantity (lithium drifting, etching, passivation of surfaces, etc) underway. S. A. Isaac Mognet GAPS: A Novel Indirect Search for Dark Mater

bgaps: A GAPS Balloon Payload A balloon-born GAPS payload (bgaps) is under active development, with a first flight planed for 2014 in Antarctica. Overall acceptance of 2.7m 2 sr. Overall width of 3m. 13 layers of Si(Li) detectors ( 200 kg of silicon). Plastic scintillator based time-of-flight system.

Simulation Work Atmospheric Simulations Development of GEANT4 based simulation to better understand backgrounds and event rate. Validated by excellent agreement with previous measurements. Optical Simulation of TOF System GEANT4 optical simulation for time-of-flight scintillator paddle design optimization. Exotic Atom Studies Ongoing work on understanding the exotic atom physics. Whole Instrument Simulation Integration of all detectors and payload structure to product whole-instrument simulation. S. A. Isaac Mognet GAPS: A Novel Indirect Search for Dark Mater

GAPS Balloon Flight Antarctic LDB flights can provide up to 40 day flights. Future ULDB flights to be 100 day.

pgaps An engineering test payload known as pgaps is scheduled to fly in 2011 from the JAXA/ISAS balloon launch facility in Taiki, Japan. This payload will consist of a plastic-scintillator based time-of-flight system and 6 commercially purchased Si(Li) detectors.

The GAPS Collaboration JAXA / ISAS: Fuke, Bando, Takada, Yoshida Columbia Univ.: Aramaki, Gahbauer, Hailey, Koglin, Madden, Mori, Tajiri UC Berkeley: Boggs, von Doetinchem Tech. Univ. Denmark: Christensen LLNL: Craig ORNL: Fabris, Ziock UCLA: Mognet, Ong, Zhang, Zweerink pgaps is funded by NASA grants in the US and by MEXT-KAKENHI grants in Japan.

Conclusions Antideuteron provide a potentially background free signature for dark matter. GAPS is a promising approach to antideuteron searches. Detector development ongoing. Science flight in 2014. Test flight this year!

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