Mechanisms of current flow in p-TlGaSe2 single crystals

Abstract

Temperature dependences of dark current, i( T), thermally stimulated current, TSC, and current - voltage, I - V, characteristics have been investigated in p-type T1GaSe(2) single crystals having different technological origins, using different contacts, in a wide temperature range and at different heating rates. Two types of initially undoped crystals with high resistivity, differing in deviation from the stoichiometry ( type 1 and type 2), have been investigated. It is shown that the mechanism of the current flow strongly depends on the technological origin of the sample. Negative TSC is observed in type 1 samples for the first time and attributed to the simultaneous release of holes and electrons from acceptor and donor states in the same temperature interval. In these types of crystals, the dark current appears due to the double injection of electrons and holes from the contacts and at high heating rates beta >= 8 - 10 K min(-1) has a thermally activated character. The parameters of subsequent impurities have been obtained using the TSC theory. The shallow donor states with extremely low capture cross sections were shown to contribute to the thermally activated processes in these types of crystals. In type 2 crystals low-frequency current oscillations, LFCO, have been observed for the first time in the temperature range 120 - 180 K. These types of crystals are characterized by nonlinear N-type I - V characteristics. Mechanisms are proposed to explain the nonlinear I - V characteristics and current oscillations.