1 MU-M MOSFET VLSI TECHNOLOGY .4. HOT-ELECTRON DESIGN CONSTRAINTS

被引:185
|
作者
NING, TH
COOK, PW
DENNARD, RH
OSBURN, CM
SCHUSTER, SE
YU, HN
机构
[1] IBM Thomas J. Watson Research Center, Yorktown Heights
来源
IEEE TRANSACTIONS ON ELECTRON DEVICES | 1979年 / 26卷 / 04期
关键词
D O I
10.1109/T-ED.1979.19433
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
An approach is described for determining the hot-electron- voltages for silicon MOSFET’s of small dimensions. The approach was followed in determining the room-temperature and the 77 K hot-electron-limited voltages for a device designed to have a minimum channel length of 1 μm. The substrate hot-electron limits were determined empirically from measurements of the emission probabilities as a function of voltage using devices of reentrant geometry. The channel hot-electron limits were determined empirically from measurements of the injection current as a function of voltage Ind from long-term stress experiments. For the 1 μm design considered, the channel hot-electron limits are lower than the substrate hot-election limits. The maximum voltage, VDS VGs, = is 4.75 V at room temperature (25°C) and 3.5 V at 77 K. More details of the voltage limits as well as the approach for determining them are discussed. Examples of circuits designed with these devices to operate within these hot-electron voltage limits are also discussed. Copyright © 1979 by The Institute of Electrical and Electronics Engineers, Inc.
引用
收藏
页码:346 / 353
页数:8
相关论文
共 50 条
  • [11] 1 MU-M MOSFET VLSI TECHNOLOGY .7. METAL SILICIDE INTERCONNECTION TECHNOLOGY - FUTURE PERSPECTIVE
    CROWDER, BL
    ZIRINSKY, S
    IEEE TRANSACTIONS ON ELECTRON DEVICES, 1979, 26 (04) : 369 - 371
  • [12] 1 MU-M MOSFET VLSI TECHNOLOGY .5. SINGLE-LEVEL POLYSILICON TECHNOLOGY USING ELECTRON-BEAM LITHOGRAPHY
    HUNTER, WR
    EPHRATH, L
    GROBMAN, WD
    OSBURN, CM
    CROWDER, BL
    CRAMER, A
    LUHN, HE
    IEEE TRANSACTIONS ON ELECTRON DEVICES, 1979, 26 (04) : 353 - 359
  • [13] 1 MU-M MOSFET VLSI TECHNOLOGY .5. SINGLE-LEVEL POLYSILICON TECHNOLOGY USING ELECTRON-BEAM LITHOGRAPHY
    HUNTER, WR
    EPHRATH, L
    GROBMAN, WD
    OSBURN, CM
    CROWDER, BL
    CRAMER, A
    LUHN, HE
    IEEE JOURNAL OF SOLID-STATE CIRCUITS, 1979, 14 (02) : 275 - 281
  • [14] ABSORPTION AND HOT-ELECTRON PRODUCTION FOR 1.05 AND 0.53 MU-M LIGHT ON SPHERICAL TARGETS
    SLATER, DC
    BUSCH, GE
    CHARATIS, G
    JOHNSON, RR
    MAYER, FJ
    SCHROEDER, RJ
    SIMPSON, JD
    SULLIVAN, D
    TARVIN, JA
    THOMAS, CE
    PHYSICAL REVIEW LETTERS, 1981, 46 (18) : 1199 - 1202
  • [15] 1 MU-M MOSFET VLSI TECHNOLOGY .2. DEVICE DESIGNS AND CHARACTERISTICS FOR HIGH-PERFORMANCE LOGIC APPLICATIONS
    DENNARD, RH
    GAENSSLEN, FH
    WALKER, EJ
    COOK, PW
    IEEE JOURNAL OF SOLID-STATE CIRCUITS, 1979, 14 (02) : 247 - 255
  • [16] 1 MU-M MOSFET VLSI TECHNOLOGY .2. DEVICE DESIGNS AND CHARACTERISTICS FOR HIGH-PERFORMANCE LOGIC APPLICATIONS
    DENNARD, RH
    GAENSSLEN, FH
    WALKER, EJ
    COOK, PW
    IEEE TRANSACTIONS ON ELECTRON DEVICES, 1979, 26 (04) : 325 - 333
  • [17] HOT-ELECTRON ENERGY-DISTRIBUTION IN SPHERICAL CANNONBALL TARGET AT 10.6 MU-M LASER WAVELENGTH
    DAIDO, H
    TERAI, K
    FUJITA, M
    MIKI, F
    NAKAI, S
    YAMANAKA, C
    JAPANESE JOURNAL OF APPLIED PHYSICS PART 2-LETTERS, 1984, 23 (11): : L833 - L835
  • [18] 10-MU-M INFRARED HOT-ELECTRON TRANSISTORS
    CHOI, KK
    DUTTA, M
    NEWMAN, PG
    SAUNDERS, ML
    IAFRATE, GJ
    APPLIED PHYSICS LETTERS, 1990, 57 (13) : 1348 - 1350
  • [19] HOT-ELECTRON GENERATION BY THE 2-PLASMON DECAY INSTABILITY IN THE LASER-PLASMA INTERACTION AT 10.6 MU-M
    EBRAHIM, NA
    BALDIS, HA
    JOSHI, C
    BENESCH, R
    PHYSICAL REVIEW LETTERS, 1980, 45 (14) : 1179 - 1182
  • [20] HOT-ELECTRON ENERGY-DISTRIBUTION IN ONE-DIMENSIONAL CANNONBALL TARGET AT 10.6 MU-M LASER WAVELENGTH
    TERAI, K
    DAIDO, H
    FUJITA, M
    NISHIMURA, H
    MIMA, K
    NAKAI, S
    YAMANAKA, C
    JAPANESE JOURNAL OF APPLIED PHYSICS PART 2-LETTERS & EXPRESS LETTERS, 1984, 23 (07): : L445 - L448
12345