Defect recombination origin of low energy excess in semiconductor detectors

Abstract: When the detection threshold in semiconductor detectors is pushed to increasingly low energies, an ``excess" signal of apparent energy release events below a few hundred eV is observed in several different kinds of detectors, hindering their sensitivity for rare event signals in this energy range. Using atomistic simulations with classical thermostat and quantum thermal bath, we show that this kind of signal is consistent with energy release from long-term recombination events of complex defects that can be formed by any kind of nuclear recoil radiation events. The recombination events are shown to have a very similar exponential dependence of energy as that observed in experiments. By detailed analysis of recombination events, we show that crossing a low energy barrier ($\lesssim$ 0.1 eV) can trigger larger energy releases in an avalanche-like effect. This explains why large energy release events can occur even down to cryogenic temperatures.