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Current Status and Future Prospects for the Light Dark Matter eXperiment

Authors :
Åkesson, Torsten
Blinov, Nikita
Brand-Baugher, Lukas
Bravo, Cameron
Bryngemark, Lene Kristian
Butti, Pierfrancesco
Doglioni, Caterina
Dukes, Craig
Dutta, Valentina
Echenard, Bertrand
Ehrlich, Ralf
Eichlersmith, Thomas
Furmanski, Andrew
Greenstein, Chloe
Group, Craig
Gogate, Niramay
Hegde, Vinay
Herwig, Christian
Hitlin, David G.
Hoang, Duc
Horoho, Tyler
Incandela, Joseph
Ketchum, Wesley
Krnjaic, Gordan
Li, Amina
Li, Shirley
Lin, Dexu
Mans, Jeremiah
Suarez, Cristina Mantilla
Masterson, Phillip
Meier, Martin
Middleton, Sophie
Moreno, Omar
Mullier, Geoffrey
Nelson, Timothy
Oyang, James
Pascadlo, Jessica
Pöttgen, Ruth
Prestel, Stefan
Pico, Luis Sarmiento
Schuster, Philip
Solt, Matthew
Tompkins, Lauren
Toro, Natalia
Tran, Nhan
Whitbeck, Andrew
Zhou, Kevin
Zichi, Laura
Åkesson, Torsten
Blinov, Nikita
Brand-Baugher, Lukas
Bravo, Cameron
Bryngemark, Lene Kristian
Butti, Pierfrancesco
Doglioni, Caterina
Dukes, Craig
Dutta, Valentina
Echenard, Bertrand
Ehrlich, Ralf
Eichlersmith, Thomas
Furmanski, Andrew
Greenstein, Chloe
Group, Craig
Gogate, Niramay
Hegde, Vinay
Herwig, Christian
Hitlin, David G.
Hoang, Duc
Horoho, Tyler
Incandela, Joseph
Ketchum, Wesley
Krnjaic, Gordan
Li, Amina
Li, Shirley
Lin, Dexu
Mans, Jeremiah
Suarez, Cristina Mantilla
Masterson, Phillip
Meier, Martin
Middleton, Sophie
Moreno, Omar
Mullier, Geoffrey
Nelson, Timothy
Oyang, James
Pascadlo, Jessica
Pöttgen, Ruth
Prestel, Stefan
Pico, Luis Sarmiento
Schuster, Philip
Solt, Matthew
Tompkins, Lauren
Toro, Natalia
Tran, Nhan
Whitbeck, Andrew
Zhou, Kevin
Zichi, Laura
Publication Year :
2022

Abstract

The constituents of dark matter are still unknown, and the viable possibilities span a vast range of masses. The physics community has established searching for sub-GeV dark matter as a high priority and identified accelerator-based experiments as an essential facet of this search strategy. A key goal of the accelerator-based dark matter program is testing the broad idea of thermally produced sub-GeV dark matter through experiments designed to directly produce dark matter particles. The most sensitive way to search for the production of light dark matter is to use a primary electron beam to produce it in fixed-target collisions. The Light Dark Matter eXperiment (LDMX) is an electron-beam fixed-target missing-momentum experiment that realizes this approach and provides unique sensitivity to light dark matter in the sub-GeV range. This contribution provides an overview of the theoretical motivation, the main experimental challenges, how LDMX addresses these challenges, and projected sensitivities. We further describe the capabilities of LDMX to explore other interesting new and standard physics, such as visibly-decaying axion and vector mediators or rare meson decays, and to provide timely electronuclear scattering measurements that will inform the modeling of neutrino-nucleus scattering for DUNE.<br />Comment: 26 pages, 17 figures. Contribution to Snowmass 2021

Details

Database :
OAIster
Publication Type :
Electronic Resource
Accession number :
edsoai.on1425540517
Document Type :
Electronic Resource