Indirect detection of unstable heavy dark matter
arXiv:hep-ph/9207261 · doi:10.1016/0370-2693(92)90097-N
Abstract
Unstable relics with lifetime longer than the age of the Universe could be the dark matter today. Electrons, photons and neutrinos are a natural outcome of their decay and could be searched for in cosmic rays and in $γ$-ray and neutrino detectors. I compare the sensitivities of these three types of searches to the mass and lifetime of a generic unstable particle. I show that if the relics constitute our galactic halo and their branching ratios into electron-positrons, photons and neutrinos are comparable, neutrino searches would probe the longest lifetimes for masses $\simge 40 \TeV$, while electron-positron searches would be better but more uncertain for lighter particles. If instead the relics are not clustered in our halo, neutrinos are more sensitive a probe than $γ$-rays for masses $\simge 700 \GeV$. A $ 1 \sqkm $ neutrino telescope should be able to explore lifetimes up to $ \sim 10^{30} \sec $ while searching for neutrinos from unstable particles above the atmospheric background.
11pp, 1 figure available on request, PHYZZX, Uppsala U. PT17-1992