TCAD-Based Flexible Fin Pitch Design for 3-nm Node 6T-SRAM Using Practical Source/Drain Patterning Scheme
SCIE
SCOPUS
- Title
- TCAD-Based Flexible Fin Pitch Design for 3-nm Node 6T-SRAM Using Practical Source/Drain Patterning Scheme
- Authors
- Lee, Junjong; Yoon, Jun-Sik; Lee, Seunghwan; Jeong, Jinsu; Baek, Rock-Hyun
- Date Issued
- 2021-03
- Publisher
- IEEE-INST ELECTRICAL ELECTRONICS ENGINEERS INC
- Abstract
- In this article, we analyzed the stability, power, performance, and area of 6T-SRAMs using a promising scaling booster, i.e., source/drain patterning (SDP) scheme for the 3-nm technology node based on 3-D TCAD simulation. SDP scheme allows to decrease the spacing between transistors by downsizing the source/drain epitaxy. Proposed 5-nm and 3-nm SDP-SRAM (SDP-SRAM(5) and SDP-SRAM(3)) are compared with conventional 5-nm node SRAM (Conv-SRAM(5)), quantitatively. Unlike a Conv-SRAM(5), SDP-SRAMs have more design margins according to the two fin position parameters: fin location adjustment (FLA) and separation pitch adjustment (SPA). The optimized layout has the maximum FLA by significantly decreasing the back-end-of-line (BEOL) bitline and internal node capacitance. Read and write static noise margins were comparable (< 10 mV) between the SDP-SRAM and Conv-SRAM. The SDP-SRAM(5) improved the read access time 18% compared to the Conv-SRAM(5) in low-power (LP) applications, but the SDP-SRAM(3) degraded it by 11% in high-performance (HP) applications because of the narrow M2 pitch. Both the SDP-SRAM(5) and SDP-SRAM(3) improved write access time about 10% compared to a Conv-SRAM(5) in LP applications. The cell area of the SDP-SRAM(3) decreased about 0.64 times compared to a Conv-SRAM(5) without severe degradation of performance. The SDP scheme provides flexible layout designs enabling a high-density SRAM, promising for 3-nm node logic applications.
- URI
- https://oasis.postech.ac.kr/handle/2014.oak/106686
- DOI
- 10.1109/TED.2021.3053508
- ISSN
- 0018-9383
- Article Type
- Article
- Citation
- IEEE TRANSACTIONS ON ELECTRON DEVICES, vol. 68, no. 3, page. 1031 - 1036, 2021-03
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