A Benchmark of Cryo-CMOS Embedded SRAM/DRAMs in 40-nm CMOS

Rob A. Damsteegt; Ramon W.J. Overwater; Masoud Babaie; Fabio Sebastiano

doi:10.1109/JSSC.2024.3385696

A Benchmark of Cryo-CMOS Embedded SRAM/DRAMs in 40-nm CMOS

Rob A. Damsteegt^*, Ramon W.J. Overwater, Masoud Babaie, Fabio Sebastiano

^*Corresponding author for this work

Research output: Contribution to journal › Article › Scientific › peer-review

Abstract

The interface electronics needed for quantum processors require cryogenic CMOS (cryo-CMOS) embedded digital memories covering a wide range of specifications. To identify the optimum architecture for each specific application, this article presents a benchmark from room temperature (RT) down to 4.2 K of custom SRAMs/DRAMs in the same 40-nm CMOS process. To deal with the significant variations in device parameters at cryogenic temperatures, such as the increased threshold voltage, lower subthreshold leakage, and increased variability, the feasibility of different memories at cryogenic temperature is assessed and specific guidelines for cryogenic memory design are drafted. Unlike at RT, the 2T low-threshold-voltage (LVT) DRAM at 4.2 K is up to $2\times$ more power efficient than both SRAMs for any access rate above 75 kHz since the lower leakage increases the retention time by $40\,000\times$ , thus sharply cutting on the refresh power and showing the potential of cryo-CMOS DRAMs in cryogenic applications.

Original language	English
Pages (from-to)	1-13
Number of pages	13
Journal	IEEE Journal of Solid-State Circuits
DOIs	https://doi.org/10.1109/JSSC.2024.3385696
Publication status	Accepted/In press - 2024

Keywords

Cryogenic CMOS (cryo-CMOS)
DRAM
eDRAM
memory
quantum computing
SRAM

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10.1109/JSSC.2024.3385696

Cite this

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title = "A Benchmark of Cryo-CMOS Embedded SRAM/DRAMs in 40-nm CMOS",

abstract = "The interface electronics needed for quantum processors require cryogenic CMOS (cryo-CMOS) embedded digital memories covering a wide range of specifications. To identify the optimum architecture for each specific application, this article presents a benchmark from room temperature (RT) down to 4.2 K of custom SRAMs/DRAMs in the same 40-nm CMOS process. To deal with the significant variations in device parameters at cryogenic temperatures, such as the increased threshold voltage, lower subthreshold leakage, and increased variability, the feasibility of different memories at cryogenic temperature is assessed and specific guidelines for cryogenic memory design are drafted. Unlike at RT, the 2T low-threshold-voltage (LVT) DRAM at 4.2 K is up to $2\times$ more power efficient than both SRAMs for any access rate above 75 kHz since the lower leakage increases the retention time by $40\,000\times$ , thus sharply cutting on the refresh power and showing the potential of cryo-CMOS DRAMs in cryogenic applications.",

keywords = "Cryogenic CMOS (cryo-CMOS), DRAM, eDRAM, memory, quantum computing, SRAM",

author = "Damsteegt, {Rob A.} and Overwater, {Ramon W.J.} and Masoud Babaie and Fabio Sebastiano",

year = "2024",

doi = "10.1109/JSSC.2024.3385696",

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journal = "IEEE Journal of Solid-State Circuits",

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AU - Damsteegt, Rob A.

AU - Overwater, Ramon W.J.

AU - Babaie, Masoud

AU - Sebastiano, Fabio

PY - 2024

Y1 - 2024

N2 - The interface electronics needed for quantum processors require cryogenic CMOS (cryo-CMOS) embedded digital memories covering a wide range of specifications. To identify the optimum architecture for each specific application, this article presents a benchmark from room temperature (RT) down to 4.2 K of custom SRAMs/DRAMs in the same 40-nm CMOS process. To deal with the significant variations in device parameters at cryogenic temperatures, such as the increased threshold voltage, lower subthreshold leakage, and increased variability, the feasibility of different memories at cryogenic temperature is assessed and specific guidelines for cryogenic memory design are drafted. Unlike at RT, the 2T low-threshold-voltage (LVT) DRAM at 4.2 K is up to $2\times$ more power efficient than both SRAMs for any access rate above 75 kHz since the lower leakage increases the retention time by $40\,000\times$ , thus sharply cutting on the refresh power and showing the potential of cryo-CMOS DRAMs in cryogenic applications.

AB - The interface electronics needed for quantum processors require cryogenic CMOS (cryo-CMOS) embedded digital memories covering a wide range of specifications. To identify the optimum architecture for each specific application, this article presents a benchmark from room temperature (RT) down to 4.2 K of custom SRAMs/DRAMs in the same 40-nm CMOS process. To deal with the significant variations in device parameters at cryogenic temperatures, such as the increased threshold voltage, lower subthreshold leakage, and increased variability, the feasibility of different memories at cryogenic temperature is assessed and specific guidelines for cryogenic memory design are drafted. Unlike at RT, the 2T low-threshold-voltage (LVT) DRAM at 4.2 K is up to $2\times$ more power efficient than both SRAMs for any access rate above 75 kHz since the lower leakage increases the retention time by $40\,000\times$ , thus sharply cutting on the refresh power and showing the potential of cryo-CMOS DRAMs in cryogenic applications.

KW - Cryogenic CMOS (cryo-CMOS)

KW - DRAM

KW - eDRAM

KW - memory

KW - quantum computing

KW - SRAM

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DO - 10.1109/JSSC.2024.3385696

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JO - IEEE Journal of Solid-State Circuits

JF - IEEE Journal of Solid-State Circuits

ER -

A Benchmark of Cryo-CMOS Embedded SRAM/DRAMs in 40-nm CMOS

Abstract

Keywords

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