A Search for Charged Excitation of Dark Matter with the KamLAND-Zen Detector
Abstract
There are many theories where a dark matter particle is part of a multiplet with an electrically charged state. If WIMP dark matter (0) is accompanied by a charged excited state (-) separated by a small mass difference, it can form a stable bound state with a nucleus. In supersymmetric models, the 0 and the - could be the neutralino and a charged slepton, such as the neutralino-stau degenerate model. The formation binding process is expected to result in an energy deposition of O(1--10 MeV), making it suitable for detection in large liquid scintillator detectors. We describe new constraints on the bound state formation with a xenon nucleus using the KamLAND-Zen 400 Phase-II dataset. In order to enlarge the searchable parameter space, all xenon isotopes in the detector were used. For a benchmark parameter set of m0 = 100 GeV and m = 10 MeV, this study sets the most stringent upper limits on the recombination cross section σ v and the decay-width of - of 2.0 × 10-31 cm3/s and 1.1 × 10-18 GeV, respectively (90\% confidence level).
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