Defect and Temperature Dependence of Tunneling in InAs/GaSb Heterojunctions

TL;DR

This study investigates the temperature dependence of tunneling in InAs/GaSb heterojunctions, revealing that interface defects significantly influence tunneling currents and that true band-to-band tunneling may be inherently limited by material imperfections.

Contribution

It provides the first detailed analysis separating intrinsic tunneling behavior from parasitic effects in InAs/GaSb heterojunctions, highlighting the role of defects and interface quality.

Findings

Conductance slope is temperature independent.

Tunneling currents depend on defect density.

Parasitic effects dominate in three-terminal devices.

Abstract

Tunnel field effect transistors (TFETs) utilizing semiconductor heterojunctions have shown promise for low energy logic but presently do not display subthreshold swings steeper than the room-temperature thermal limit of 60 mV/decade. These devices also show a pronounced temperature dependence that is not characteristic of a tunneling process. Herein, we explore these aspects by studying the temperature dependence of two-terminal InAs/GaSb heterojunctions, allowing for the true nature of tunneling at the interface to be seen without convolution from other three-terminal parasitic effects such as gate oxide traps. We compare the temperature dependence of peak current, excess current, and conductance slope for InAs/GaSb interfaces with and without interface defects. We identify that the tunnel and excess currents depend on temperature and defect density and propose that the ultimate leakage current in TFETs based on these materials will be affected by defects and inhomogeneity at the interface. We determine that the conductance slope, a two-terminal analog to subthreshold slope, does not depend on temperature, contrasting sharply with the heavy temperature dependence seen in three terminal devices in literature. We propose that TFETs based on this and similar materials systems are dominated by parasitic effects such as tunneling into oxide trap states, or other parasitics that are not intrinsic to the heterojunction itself, and that in the absence of these effects, the true steepness from band-to-band tunneling is limited by defects and inhomogeneity at the interface.