This paper investigates the degradation of vertically aligned gallium nitride (GaN) nanowire (NW) arrays submitted to gate bias stress and UV light. Based on electrical tests and simulations, we demonstrate the existence of trapping processes that depend on the applied stress voltage V Gstress and on the applied light during stress (wavelength, λ). We demonstrate the following original results: 1) for positive and negative V Gstress conditions, no significant variation in dc characteristics is observed when the samples are stressed in dark and 2) when the devices are submitted to negative V Gstress and to UV light, a positive variation in threshold voltage (V th ) is observed. The positive V th shift is ascribed to the transfer and trapping of electrons from the gate metal to the oxide, promoted by UV light. We also evaluated the temperature dependence of the threshold voltage shift under UV light. We demonstrated an increased trapping at higher temperatures, indicating a role of thermionic processes in electron trapping. On the other hand, detrapping from oxide states proceeds through defect-mediated conduction, i.e., is limited by the number of available states.
Demonstration of UV-Induced Threshold Voltage Instabilities in Vertical GaN Nanowire Array-Based Transistors
Ruzzarin, M.;
2019-01-01
Abstract
This paper investigates the degradation of vertically aligned gallium nitride (GaN) nanowire (NW) arrays submitted to gate bias stress and UV light. Based on electrical tests and simulations, we demonstrate the existence of trapping processes that depend on the applied stress voltage V Gstress and on the applied light during stress (wavelength, λ). We demonstrate the following original results: 1) for positive and negative V Gstress conditions, no significant variation in dc characteristics is observed when the samples are stressed in dark and 2) when the devices are submitted to negative V Gstress and to UV light, a positive variation in threshold voltage (V th ) is observed. The positive V th shift is ascribed to the transfer and trapping of electrons from the gate metal to the oxide, promoted by UV light. We also evaluated the temperature dependence of the threshold voltage shift under UV light. We demonstrated an increased trapping at higher temperatures, indicating a role of thermionic processes in electron trapping. On the other hand, detrapping from oxide states proceeds through defect-mediated conduction, i.e., is limited by the number of available states.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.