Architecture and Optimization of 2T (Footprint) SRAM

A 6T-SRAM bitcell with the footprint of only two transistors is demonstrated by stacking four n-type vertical gate-all-around transistors (VFET) on two pFinFETs. The local interconnects are all within the footprint of the two bottom pFinFETs. The bitcell area is 0.014~\mu \text{m}^{{2}} considerin...

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Bibliographic Details
Published in:IEEE transactions on electron devices 2021-10, Vol.68 (10), p.4918-4924
Main Authors: Chung, Chia-Che, Lin, Hsin-Cheng, Huang, Bo-Wei, Tsen, Chia-Jung, Liu, C. W.
Format: Article
Language:English
Subjects:
Area
Circuits
Computer architecture
FinFET
Logic gates
Metals
Microprocessors
Optimization
Random access memory
Semiconductor devices
Stability
static random access memory (SRAM)
Threshold voltage
Transistors
vertical gate-all-around transistor (VFET)
Wireless sensor networks
Work functions
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Summary:A 6T-SRAM bitcell with the footprint of only two transistors is demonstrated by stacking four n-type vertical gate-all-around transistors (VFET) on two pFinFETs. The local interconnects are all within the footprint of the two bottom pFinFETs. The bitcell area is 0.014~\mu \text{m}^{{2}} considering the experimentally achievable metal pitch of 52 nm and bottom pFinFETs of 5 nm node. It can be further reduced to 0.009~\mu \text{m}^{{2}} considering the metal pitch of 30 nm. The minimum operating voltage is analyzed considering the dominant work function variation. The fin height of pFETs and the gate length of nFETs are used to optimize the read/write static noise margin (RSNM/WSNM) for the same bitcell area. The cell ratio is insensitive to pFET fin height and nFET gate length, leading the read stability to be less affected by pFET fin height and nFET gate length as compared to the write stability. The minimum operating voltage is reduced to 0.59 V using pFET fin height of 15 nm and nFET gate length of 20 nm to balance the read/write SNM without assist circuit techniques. The minimum operating voltage can be further improved to 0.56 V by optimizing the threshold voltage of −0.27 and 0.27 V for pFETs and nFETs, respectively. Moreover, using the negative bitline (NBL) technique can provide an additional 320 mV reduction on the write minimum operating voltage.
ISSN:0018-9383
1557-9646
DOI:10.1109/TED.2021.3107474