Performance advantage of Schottky source/drain in ultrathin-body silicon-on-insulator and dual-gate CMOS

被引：43

作者：

Connelly, D ^{[1
]}

Faulkner, C ^{[1
]}

Grupp, DE ^{[1
]}

机构：

[1] Acorn Technol, Palo Alto, CA 94061 USA

来源：

IEEE TRANSACTIONS ON ELECTRON DEVICES | 2003年 / 50卷 / 05期

关键词：

CMOSFET circuits; MOS devices; Schottky barriers; semiconductor device modeling; semiconductor-metal interfaces; silicon; simulation;

D O I：

10.1109/TED.2003.813229

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：

Here, for the first time, advanced simulation models are used to investigate the performance advantage of Schottky source/drain ultrathin-silicon technologies at a 25-nm gate length target. Schottky and doped source/drain MOSFETs were optimized and compared using a novel benchmark. Mixed-mode simulations of optimized devices in a two-stage NAND chain show an approximate 45% speed advantage of Schottky source/drain for one set of parameter choices. Contact requirements for Schottky source/drain, and for doped source/drain relative to ITRS targets through 2016, are discussed.

引用

页码：1340 / 1345

页数：6

共 27 条

[1] QUANTUM CORRECTION TO THE EQUATION OF STATE OF AN ELECTRON-GAS IN A SEMICONDUCTOR [J].

ANCONA, MG ;

IAFRATE, GJ .

PHYSICAL REVIEW B, 1989, 39 (13) :9536-9540

[2] Relating expectations to automatically recovered design patterns [J].

Asencio, A ;

Cardman, S ;

Harris, D ;

Laderman, E .

NINTH WORKING CONFERENCE ON REVERSE ENGINEERING, PROCEEDINGS, 2002, :87-96

[3] MOSFET modeling into the ballistic regime [J].

Bude, JD .

2000 INTERNATIONAL CONFERENCE ON SIMULATION OF SEMICONDUCTOR PROCESSES AND DEVICES, 2000, :23-26

[4] ELECTRON AND HOLE DRIFT VELOCITY-MEASUREMENTS IN SILICON AND THEIR EMPIRICAL RELATION TO ELECTRIC-FIELD AND TEMPERATURE [J].

CANALI, C ;

MAJNI, G ;

MINDER, R ;

OTTAVIANI, G .

IEEE TRANSACTIONS ON ELECTRON DEVICES, 1975, 22 (11) :1045-1047

[5] CARRIER MOBILITIES IN SILICON EMPIRICALLY RELATED TO DOPING AND FIELD [J].

CAUGHEY, DM ;

THOMAS, RE .

PROCEEDINGS OF THE INSTITUTE OF ELECTRICAL AND ELECTRONICS ENGINEERS, 1967, 55 (12) :2192-+

[6]

Connelly D., 2002, Device Research Conference (Cat. No.02TH8606), P77, DOI 10.1109/DRC.2002.1029522

[7] Macroscopic simulation of quantum mechanical effects in 2-D MOS devices via the density gradient method [J].

Connelly, D ;

Yu, ZP ;

Yergeau, D .

IEEE TRANSACTIONS ON ELECTRON DEVICES, 2002, 49 (04) :619-626

[8] Improved device technology evaluation and optimization [J].

Connelly, D ;

Foisy, M .

2000 INTERNATIONAL CONFERENCE ON SIMULATION OF SEMICONDUCTOR PROCESSES AND DEVICES, 2000, :155-158

[9]

CONNELLY D, 2001, P 2001 IEEE SISPAD, P90

[10]

CONNELLY D, 2003, IN PRESS IEEE ELECT

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