The Impact of TaS2-Augmented Interconnects on Circuit Performance: A Temperature-Dependent Analysis
Abstract
Monolayer TaS2 is being explored as a future liner/barrier to circumvent the scalability issues of the state-of-the-art interconnects. However, its large vertical resistivity poses some concerns and mandates a comprehensive circuit analysis to understand the benefits and trade-offs of this technology. In this work, we present a detailed temperature-dependent modeling framework of TaS2-augmented copper (Cu) interconnects and provide insights into their circuit implications. We build temperature-dependent 3D models for Cu-TaS2 interconnect resistance capturing surface scattering and grain boundary scattering and integrate them in an RTL-GDSII design flow based on ASAP7 7nm process design kit. Using this framework, we perform synthesis and place-and-route (PnR) for advanced encryption standard (AES) circuit at different process and temperature corners and benchmark the circuit performance of Cu-TaS2 interconnects against state-of-the-art interconnects. Our results show that Cu-TaS2 interconnects yield an enhancement in the effective clock frequency of the AES circuit by 1%-10.6%. Considering the worst-case process-temperature corner, we further establish that the vertical resistivity of TaS2 must be below 22 k-nm to obtain performance benefits over conventional interconnects.
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