A Screening Methodology for VMIN Drift in SRAM Arrays with Application to Sub-65nm Nodes

M. Ball,J. Rosal,Randy Mckee,Wk. Loh,Theodore W. Houston,R. Garcia,Jayesh C. Raval,D. Li,R. Hollingsworth,R. Gury,Robert H. Eklund,J. Vaccani,B. Castellano,F. Piacibello,S. Ashburn,Alwin J. Tsao,Anand T. Krishnan,Jay Ondrusek,T. Anderson

A Screening Methodology for VMIN Drift in SRAM Arrays with Application to Sub-65nm Nodes

2006

M. Ball
J. Rosal
Randy Mckee
Wk. Loh
Theodore W. Houston
R. Garcia
Jayesh C. Raval
D. Li
R. Hollingsworth
R. Gury
Robert H. Eklund
J. Vaccani
B. Castellano
F. Piacibello
S. Ashburn
Alwin J. Tsao
Anand T. Krishnan
Jay Ondrusek
T. Anderson

SRAMs are an integral part of system on chip devices. With transistor and gate length scaling to 65nm/45nm nodes, SRAM stability across the product's lifetime has become a challenge. Negative bias temperature instability, defects, or other phenomena that may manifest itself as a transistor threshold voltage (V T ) increase can result in VMIN drift of SRAM memory cells through burn-in and/or operation. A direct assessment at time-zero is difficult because the transistor V T has not yet shifted, and therefore no capability to screen VMIN shift at time zero can be developed. This work describes a methodology developed on 65nm low power and high performance process technologies at Texas Instruments for screening SRAM cells at time zero before they become reliability issues

Keywords:

AND gate
Electronic engineering
System on a chip
Thermal stability
Transistor
Length scale
Threshold voltage
Negative-bias temperature instability
Static random-access memory
Physics
time zero
Electrical engineering
Scaling

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