TY - JOUR
T1 - Metastable nuclear isomers as dark matter accelerators
AU - Pospelov, Maxim
AU - Rajendran, Surjeet
AU - Ramani, Harikrishnan
N1 - Publisher Copyright:
© 2020 authors. Published by the American Physical Society.
PY - 2020/3/1
Y1 - 2020/3/1
N2 - Inelastic dark matter and strongly interacting dark matter are poorly constrained by direct detection experiments since they both require the scattering event to deliver energy from the nucleus into the dark matter in order to have observable effects. We propose to test these scenarios by searching for the collisional deexcitation of metastable nuclear isomers by the dark matter particles. The longevity of these isomers is related to a strong suppression of γ- and β-transitions, typically inhibited by a large difference in the angular momentum for the nuclear transition. The collisional deexcitation by dark matter is possible since heavy dark matter particles can have a momentum exchange with the nucleus comparable to the inverse nuclear size, hence lifting tremendous angular momentum suppression of the nuclear transition. This deexcitation can be observed either by searching for the direct effects of the decaying isomer, or through the rescattering or decay of excited dark matter states in a nearby conventional dark matter detector setup. Existing nuclear isomer sources such as naturally occurring Ta180m, Ba137m produced in decaying Cesium in nuclear waste, Lu177m from medical waste, and Hf178m from the Department of Energy storage can be combined with current dark matter detector technology to search for this class of dark matter.
AB - Inelastic dark matter and strongly interacting dark matter are poorly constrained by direct detection experiments since they both require the scattering event to deliver energy from the nucleus into the dark matter in order to have observable effects. We propose to test these scenarios by searching for the collisional deexcitation of metastable nuclear isomers by the dark matter particles. The longevity of these isomers is related to a strong suppression of γ- and β-transitions, typically inhibited by a large difference in the angular momentum for the nuclear transition. The collisional deexcitation by dark matter is possible since heavy dark matter particles can have a momentum exchange with the nucleus comparable to the inverse nuclear size, hence lifting tremendous angular momentum suppression of the nuclear transition. This deexcitation can be observed either by searching for the direct effects of the decaying isomer, or through the rescattering or decay of excited dark matter states in a nearby conventional dark matter detector setup. Existing nuclear isomer sources such as naturally occurring Ta180m, Ba137m produced in decaying Cesium in nuclear waste, Lu177m from medical waste, and Hf178m from the Department of Energy storage can be combined with current dark matter detector technology to search for this class of dark matter.
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U2 - 10.1103/PhysRevD.101.055001
DO - 10.1103/PhysRevD.101.055001
M3 - Article
AN - SCOPUS:85083588645
SN - 2470-0010
VL - 101
JO - Physical Review D
JF - Physical Review D
IS - 5
M1 - 055001
ER -