Journal article

Atmospheric neutrinos in next-generation xenon and argon dark matter experiments

JL Newstead, RF Lang, LE Strigari

Physical Review D | Published : 2021

Abstract

We study the sensitivity of future xenon- and argon-based dark matter and neutrino detection experiments to low-energy atmospheric neutrinos. Not accounting for experimental backgrounds, the primary obstacle for identifying nuclear recoils induced by atmospheric neutrinos in xenon is the tail of the electron recoil distribution due to pp solar neutrinos. We use the NEST code to model the solar and atmospheric neutrino signals in a xenon detector and find that an exposure of 700 tonne-years will produce a 5s detection of atmospheric neutrinos. We explore the effect of different detector properties and find that a sufficiently long electron lifetime is essential to the success of such a measur..

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University of Melbourne Researchers

Grants

Awarded by Australian Research Council


Funding Acknowledgements

We thank Amanda Depoian for useful comments on this manuscript. The work of L. E. S. is supported by DOE Grant No. de-sc0010813 and that of R. F. L. and J. L. N. by NSF Grant No. PHY-1719271. J. L. N. is supported in part by the Australian Research Council. J. L. N. thanks The Mitchell Institute for their hospitality while a portion of this work was completed.