Enhancing and mapping thermal boundary conductance across bonded Si-SiC interface
Rulei Guo, Bin Xu, Fengwen Mu, Junichiro Shiomi
Abstract
• A 4-inch Si/4H-SiC wafer was fabricated by the surface-activated bonding method • The sample show high quality with very low strain in the Si device layer. • A 78% increase in the TBC of the bonded interface compared to a previous study. • The real spatial distribution of TBC was measured via a mathematical analysis. SiC is a promising substrate for Si-on-insulator (SOI) wafers for efficient thermal management owing to its high thermal conductivity and large bandgap. However, fabricating a Si device layer on a SiC substrate with a high and uniform thermal-boundary conductance (TBC) at the wafer scale is challenging. In this study, a 4-inch Si-on-SiC wafer was fabricated using a room-temperature surface-activated bonding method, and the TBC was measured using the time-domain thermoreflectance (TDTR) method. The obtained TBC was 109 MW/m 2 K in the as-bonded sample, improving to 293 MW/m 2 K after annealing at 750 °C, representing a 78 % increase compared to previously reported values for a Si–SiC interface formed by bonding methods. Such enhancement is attributed to the absence of an oxide layer at the interface. Furthermore, we assessed the actual spatial distribution of the TBC in the SOI system by combining the TDTR mapping with a mathematical model to remove the influence of random errors in the experiment. The spatial distributions before and after annealing were 7 % and 17 %, respectively. Such variation highlights the need to consider the TBC distribution when designing thermal management systems.