Abstract
Cryogenic CMOS technology provides a promising approach to surpass the Boltzmann limit and advance Moore's Law, addressing the increasing demand for high-performance computing. However, at cryogenic temperatures, the subthreshold swing (SS) of the device saturates due to the band-tail effect. This study presents a 3-vertically stacked gate-all-around nanosheet (NS) transistor featuring room-temperature O radical interface passivation. This approach leverages the high reactivity of O radicals to minimize etch-induced damage, passivate interface defects, reduce thermal budget, and ensure uniformity in complex 3D structures. Structural characterization revealed a uniform 0.76-nm-thick interface layer, with a surface roughness of 0.103 nm and an interface trap density of 2.72 × 10(11) cm(-2)·eV(-1) at 300 K. Thereby, the band-tail-induced SS saturation at cryogenic temperatures is effectively mitigated. Experimental results confirm a lower characteristic temperature T(v) for reaching the saturation plateau, and a saturated SS of 15.4 mV/dec at 4.5 K. Furthermore, reducing disorder-induced defects substantially suppresses the band tail state-assisted carrier emission, thereby minimizing subthreshold leakage. This enables the device to achieve an off-state current below 1 pA/μm at a temperature under 77 K, reaching 0.18 pA/μm at 4.5 K. Additionally, a reduction in 25.4% in drain-induced barrier lowering (DIBL), with a 9% boost in transconductance (G(m)) peak is achieved at 4.5 K. The enhanced subthreshold switching, reduced leakage, and improved G(m) in this interfacial-optimized NS FET strongly supports cryo-CMOS as a viable solution for energy-efficient computing.