Abstract

This article explores and evaluates six-transistor static random access memory (SRAM) bitcell design options for sequential and monolithic complementary field-effect transistors (CFET) in 5-Å-compatible (A5) and 3-Å-compatible (A3) technology. A5 CFET offers up to 55% and 40% SRAM bitcell area scaling due to stacked architecture as compared to 14-Å-compatible (A14) nanosheet (NS) technology and 10-Å-compatible (A10) forksheet (FS) technology counterparts, respectively. A dielectric isolation wall (DIW) between gates is introduced in A3 CFET SRAM as a scaling booster. Replacement of gate-cuts with DIW results in up to 17% bitcell area scaling in A3 as compared to A5 CFET SRAM. However, aggressive area scaling introduces routing complexity and limits the node-to-node power and performance (PP) gain. Thus, the interconnect design guidelines are provided to overcome these challenges for power, performance, and area (PPA) enhancements of high-density (HD) SRAM.