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CFET SRAM DTCO, Interconnect Guideline, and Benchmark for CMOS Scaling

Hsiao-Hsuan Liu, Shairfe Muhammad Salahuddin, Boon Teik Chan, P. Schuddinck, Yang Xiang, Geert Hellings, Pieter Weckx, Julien Ryckaert, Francky Catthoor

2023IEEE Transactions on Electron Devices47 citationsDOIOpen Access PDF

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.

Topics & Concepts

Static random-access memoryCMOSTransistorElectronic engineeringScalingNode (physics)Benchmark (surveying)InterconnectionElectrical engineeringComputer scienceEngineeringVoltageTelecommunicationsGeographyGeometryStructural engineeringMathematicsGeodesySemiconductor materials and devicesAdvancements in Semiconductor Devices and Circuit DesignLow-power high-performance VLSI design
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