3D Modeling of Spatio-temporal Heat-transport in III-V Gate-all-around Transistors Allows Accurate Estimation and Optimization of Nanowire Temperature

Excellent electrostatic control offered by gate-all-around (GAA) geometry makes multinanowire (multi-NW) MOSFET a promising candidate for sub-10-nm technology nodes. Unfortunately, the GAA geometry is susceptible to the increased self-heating due to poor heat dissipation from the nanowires (NWs) to the substrate. Therefore, an understanding of spatio-temporal temperature rise, AT(x, y, z; t), at the NW level is important for predicting activity-induced variability within an IC, as well as characterization of various reliability issues, such as, NBTI, PBTI, HCI, and TDDB that depend sensitively on self-heating. In this paper, a 3-D electrothermal simulation model is developed to explore and interpret self-heating and heat dissipation in GAA devices. Our results identify complex heat dissipation pathways characterized by multiple time constants. First, the nanowires heat up quickly (τ_GAA-NW ~ n_Sec), then heat spreads all over the gate contact pad (τ_G-pad ~ 100 nSec), and finally, the heat exits through the heat sink at the bottom of the substrate (τ_sub ~ mSec). A systematic thermoreflectance measurement of temperature helps us to identify the time constants, and validates the model. Our results have implications for the design, characterization, circuit-operation, and reliability of high-performance GAA devices.