Ultralow-power SRAM technology

被引:40
作者
Mann, RW
Abadeer, WW
Breitwisch, MJ
Bula, O
Brown, JS
Colwill, BC
Cottrell, PE
Crocco, WG
Furkay, SS
Hauser, MJ
Hook, TB
Hoyniak, D
Johnson, JM
Lam, CH
Mih, RD
Rivard, J
Moriwaki, A
Phipps, E
Putnam, CS
Rainey, BA
Toomey, JJ
Younus, MI
机构
[1] IBM Microelect Div, Burlington Facil, Essex Jct, VT 05452 USA
[2] IBM Microelect Div, E Fishkill Facil, Semicond Res & Dev Ctr, Hopewell Jct, NY 12533 USA
[3] Yasu Semicond Corp, Shiga, Japan
来源
IBM JOURNAL OF RESEARCH AND DEVELOPMENT | 2003年 / 47卷 / 5-6期
关键词
INDUCED DRAIN LEAKAGE; OXIDE; FLUCTUATIONS; SUPPRESSION; MOSFETS; DESIGN;
D O I
10.1147/rd.475.0553
中图分类号
TP3 [计算技术、计算机技术];
学科分类号
0812 ;
摘要
An ultralow-standby-power technology has been developed in both 0.18-mum and 0.13-mum lithography nodes for embedded and standalone SRAM applications. The ultralow-leakage six-transistor (6T) SRAM cell sizes are 4.81 mum(2) and 2.34 mum(2) corresponding respectively to the 0.18-mum and 0.13-mum design dimensions. The measured array standby leakage is equal to an average cell leakage current of less than 50 fA per cell at 1.5 V, 25degreesC and is less than 400 fA per cell at 1.5 V, 85degreesC. Dual gate oxides of 2.9 nm and 5.2 nm provide optimized cell leakage, I/O compatibility, and performance. Analyses of the critical parasitic leakage components and paths within the 6T SRAM cell are reviewed in this paper. In addition to the well-known gate-oxide leakage limitation for ULP technologies, three additional limits facing future scaled ULP technologies are discussed.
引用
收藏
页码:553 / 566
页数:14
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