Highly area efficient and cost effective double stacked S3(stacked single-crystal Si) peripheral CMOS SSTFT and SRAM cell technology for 512M bit density SRAM

被引：0

作者：

Jung, SM ^{[1
]}

Lim, H ^{[1
]}

Cho, WS ^{[1
]}

Cho, HS ^{[1
]}

Yeo, CD ^{[1
]}

Kang, YH ^{[1
]}

Bae, DG ^{[1
]}

Na, J ^{[1
]}

Kwak, KH ^{[1
]}

Choi, BY ^{[1
]}

Kim, SJ ^{[1
]}

Jeong, JH ^{[1
]}

Chang, YC ^{[1
]}

Jang, JH ^{[1
]}

Kim, JH ^{[1
]}

Kim, K ^{[1
]}

Ryu, BI ^{[1
]}

机构：

[1] Samsung Elect, R&D Ctr, Yongin, Kyungki Do, South Korea

来源：

IEEE INTERNATIONAL ELECTRON DEVICES MEETING 2004, TECHNICAL DIGEST | 2004年

关键词：

D O I：

暂无

中图分类号：

TM [电工技术]; TN [电子技术、通信技术];

学科分类号：

0808 ; 0809 ;

摘要：

For the first time, the highest density SRAM, such as 512M bit SRAM, is developed by implementing the smallest 25F(2) S-3 SRAM cell technology, whose cell size is 0.16mum(2), and area saving peripheral SSTFT( Stacked Single-crystal Thin Film Transistor) technology. The SSTFT are used as the peripheral CMOS transistors as well as the cell transistors to save area to make the SRAM products comparative to the DRAM cell based products in the density and the cost. In the S-3 SRAM cell, the load PMOS and pass NMOS transistors are stacked over the planar pull-down NMOS transistors to drastically reduce the cell size. Also, in a periphery, the core logic transistors are stacked on the ILD to save the layout area for maximizing cell efficiency for the products.

引用

页码：265 / 268

页数：4

共 7 条

[1] The revolutionary and truly 3-dimensional 25F2 SRAM technology with the smallest S3 (stacked single-crystal Si) cell, 0.16um2, and SSTFT (stacked single-crystal thin film transistor) for ultra high density SRAM
Jung, SM
Jang, J
Cho, W
Moon, J
Kwak, K
Choi, B
Hwang, B
Lim, H
Jeong, J
Kim, J
Kim, K
2004 SYMPOSIUM ON VLSI TECHNOLOGY, DIGEST OF TECHNICAL PAPERS, 2004, : 228 - 229
[2] 65nm high performance SRAM technology with 25F2, 0.16um2 S3 (stacked single-crystal Si) SRAM cell, and stacked peripheral SSTFT for ultra high density and high speed applications
Lim, H
Jung, SM
Rah, Y
Ha, T
Park, H
Chang, C
Cho, W
Park, J
Son, B
Jeong, J
Cho, H
Choi, B
Kim, K
PROCEEDINGS OF ESSDERC 2005: 35TH EUROPEAN SOLID-STATE DEVICE RESEARCH CONFERENCE, 2005, : 549 - 552
[3] Novel 3-dimensional 46F2 SRAM technology with 0.294um2 S3 (stacked single-crystal Si) cell and SSTFT (stacked single-crystal thin film transistor)
Jang, JH
Jung, SM
Kang, YH
Cho, WS
Moon, JH
Yeo, CD
Kwak, KH
Choi, BH
Hwang, BJ
Jung, WR
Kim, SJ
Kim, JH
Na, JH
Lim, H
Jeong, JH
Kim, K
ESSDERC 2004: PROCEEDINGS OF THE 34TH EUROPEAN SOLID-STATE DEVICE RESEARCH CONFERENCE, 2004, : 445 - 448
[4] Highly cost effective and high performance 65nm S3 (Stacked Single-crystal Si) SRAM technology with 25F2, 0.16um2 cell and doubly stacked SSTFT cell transistors for ultra high density and high speed applications
Jung, SM
Rah, Y
Ha, T
Park, H
Chang, CL
Lee, S
Yun, JH
Cho, W
Lim, H
Park, J
Jeong, J
Son, B
Jang, J
Choi, B
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2005 Symposium on VLSI Technology, Digest of Technical Papers, 2005, : 220 - 221
[5] Fabrication and characteristics of novel load PMOS SSTFT(stacked single-crystal thin film transistor) for 3-dimensional SRAM memory cell
Kang, YH
Jung, SM
Jang, JH
Moon, JH
Cho, WS
Yeo, CD
Kwak, KH
Choi, BH
Hwang, BJ
Jung, WR
Kim, SJ
Kim, JH
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Lim, H
Jeong, JH
Kim, K
2004 IEEE INTERNATIONAL SOI CONFERENCE, PROCEEDINGS, 2004, : 127 - 129
[6] High speed and highly cost effective 72M bit density S3SRAM technology with doubly stacked Si layers, peripheral only CoSix layers and tungsten shunt W/L scheme for standalone and embedded memory
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[7] 64Mb mobile stacked single-crystal SiSRAM (S3RAM) with selective dual pumping scheme (SDPS) and multi cell burn-in scheme (MCBS) for high density and low power SRAM
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Mo, HS
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Kang, SB
Han, GH
Park, JM
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Kim, SY
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Byun, HG
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