Neutralino event rates in dark matter detectors

ABSTRACT: The expected event rates for {\tilde Z_{1}} dark matter for a variety of dark matter detectors are studied over the full parameter space with tan \beta\leq 20 for supergravity grand unified models. Radiative breaking constraints are implemented and effects of the heavy netural Higgs included as well as loop corrections to the neutral Higgs sector. The parameter space is restricted so that the {\tilde Z_{1}} relic density obeys 0.10 \leq\Omega_{\tilde Z_{1}}h^2\leq 0.35, consistent with the COBE data and astronomical determinations of the Hubble constant. It is found that the best detectors sensitive to coherrent {\tilde Z_{1}} scattering (e.g. Pb) is about 5-10 more sensitive than those based on incoherrent spin dependent scattering (e.g. CaF). In general, the dark matter detectors are most sensistive to the large tan \beta and small m_o and m_{\tilde g} sector of the parameter space.