Engineering Cryogenic FETs: Addressing SCEs and Impact of Interface Traps Down to 2 K Temperature

This paper presents a comprehensive design and benchmarking of cryogenic bulk-FET using a calibrated TCAD model integrating 2-D electrostatics and interface trap effects across temperatures from T = 2 K to 300 K. For a 28-nm node FET, transport appears predominately ballistic at T = 2 K, shifting toward quasi-ballistic transport with increasing temperature. Short-channel effects (SCEs) dominate cryogenic benefits at Lg = 25 nm for T < 25 K, as evidenced by a modest improvement in the minimum subthreshold swing and threshold voltage roll-off with temperature in this range. Additionally, localized defects exacerbate SCEs, increasing the OFF current and subthreshold swing, while broader trap distributions yield higher carrier mobility. Higher trap densities amplify SCEs, degrade surface mobility, and worsen threshold voltage roll-off. This study also addresses the impact of technology scaling parameters, such as oxide thickness and gate length, on SCEs at cryogenic temperatures. The calibrated TCAD deck aligns closely with experimental data for low and high drain biases at T = 4.2 K, 77 K, and 300 K, providing robust methodologies for simulating and predicting the characteristics of short-channel cryogenic FETs. The detailed TCAD Sentaurus deck implementation methodology is explained, which can be further used to design low-temperature technologies. This work can serve as a guideline for optimizing technology nodes and channel/oxide scaling to achieve minimal SCEs, maximum ON/OFF ratio, and enhanced surface mobility.