Novel 3-dimensional 46F/sup 2/ SRAM technology with 0.294um/sup 2/ S/sup 3/ (stacked single-crystal Si) cell and SSTFT (stacked single-crystal thin film transistor)

Jae-Hoon Jang,Sung-Gon Jung,Y. H. Kang,Wooyoung Cho,J.H. Moon,Chadong Yeo,Kun-Ho Kwak,Byeong-In Choi,B.J. Hwang,W.R. Jung,Si-Hong Kim,J.H. Kim,J.H. Na,Hyun-Seok Lim,J.H. Jeong,Kinam Kim

Novel 3-dimensional 46F/sup 2/ SRAM technology with 0.294um/sup 2/ S/sup 3/ (stacked single-crystal Si) cell and SSTFT (stacked single-crystal thin film transistor)

2004

Jae-Hoon Jang
Sung-Gon Jung
Y. H. Kang
Wooyoung Cho
J.H. Moon
Chadong Yeo
Kun-Ho Kwak
Byeong-In Choi
B.J. Hwang
W.R. Jung
Si-Hong Kim
J.H. Kim
J.H. Na
Hyun-Seok Lim
J.H. Jeong
Kinam Kim

We have realized a 46F/sup 2/ SRAM cell size of 0.294 /spl mu/m/sup 2/ with 80 nm technology and single stack S/sup 3/ cell technology. SSTFTs and vertical node contacts are major keys in the S/sup 3/ cell technology. The stacked single crystal silicon thin film is developed for the load pMOS SSTFT of the S/sup 3/ SRAM cell. The load pMOS SSTFT is stacked on ILD to reduce the SRAM cell size. Fully working 64 Mbit SRAM is achieved by this S/sup 3/ cell technology. The basic reliability of SSTFT, with 80 nm length, is also investigated in this study.

Keywords:

Megabit
Thin film
Computer science
Thin-film transistor
Electronic engineering
Single crystal
PMOS logic
Static random-access memory
Silicon
sram cell
single crystal silicon
cell technology

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