Ion implant modeling for ULSI CMOS technology development and manufacturing

被引:0
|
作者
Tasch, AF
机构
来源
PROCEEDINGS OF THE FOURTH INTERNATIONAL SYMPOSIUM ON PROCESS PHYSICS AND MODELING IN SEMICONDUCTOR TECHNOLOGY | 1996年 / 96卷 / 04期
关键词
D O I
暂无
中图分类号
O646 [电化学、电解、磁化学];
学科分类号
081704 ;
摘要
Ion implantation is widely used in integrated circuit manufacturing today and is expected to continue to be the dominant doping tool in the future. The reduced thermal budgets and scaled devices in succeeding generations of CMOS technology have resulted in a strong need for accurate models for the profiles of both the as-implanted impurities and the implant-induced damage. The ion implant models developed at the University of Texas at Austin will be described, which include computationally efficient analytical models and physically based models for B, BF2, As, and P.
引用
收藏
页码:438 / 452
页数:15
相关论文
共 50 条
  • [1] Scientific ULSI manufacturing technology
    Ohmi, T
    [J]. IEICE TRANSACTIONS ON ELECTRONICS, 1996, E79C (03) : 255 - 255
  • [2] Modeling of variation in submicrometer CMOS ULSI technologies
    Springer, Scott K.
    Lee, Sungjae
    Lu, Ning
    Nowak, Edward J.
    Plouchart, Jean-Olivier
    Watts, Josef S.
    Williams, Richard Q.
    Zamdmer, Noah
    [J]. IEEE TRANSACTIONS ON ELECTRON DEVICES, 2006, 53 (09) : 2168 - 2178
  • [3] Wafer inspection technology challenges for ULSI manufacturing
    Stokowski, S
    Vaez-Iravani, M
    [J]. CHARACTERIZATION AND METROLOGY FOR ULSI TECHNOLOGY, 1998, 449 : 405 - 415
  • [4] ULSI technology development trend
    Okuto, Y
    Kunio, T
    [J]. 2000 INTERNATIONAL SEMICONDUCTOR CONFERENCE, VOLS 1 AND 2, CAS 2000 PROCEEDINGS, 2000, : 3 - 9
  • [5] SELF-ALIGNED ION IMPLANT MASKING FOR CMOS VLSI TECHNOLOGY
    PIMBLEY, JM
    GHEZZO, M
    [J]. ELECTRON DEVICE LETTERS, 1982, 3 (04): : 99 - 100
  • [6] LIMITATION OF SPACER THICKNESS IN TITANIUM SALICIDE ULSI CMOS TECHNOLOGY
    SUNG, JJ
    LU, CY
    [J]. IEEE ELECTRON DEVICE LETTERS, 1989, 10 (11) : 481 - 483
  • [7] Nitridation of gate and tunnel oxides employed in CMOS-ULSI technology
    Gerardi, C
    Melanotte, M
    Crivelli, B
    Zonca, R
    Alessandri, M
    [J]. MICRON, 2000, 31 (03) : 291 - 297
  • [8] TEM studies of ion implantation damage in ULSI technology
    Jones, KS
    Law, ME
    Brindos, R
    Keys, P
    [J]. MICROSCOPY OF SEMICONDUCTING MATERIALS 2001, 2001, (169): : 349 - 356
  • [9] Cycle time improvement in manufacturing nitrided gate oxides for ULSI CMOS applications
    Yoon, G
    Epstein, Y
    [J]. 1996 ADVANCED SEMICONDUCTOR MANUFACTURING CONFERENCE AND WORKSHOP - ASMC 96 PROCEEDINGS: THEME - INNOVATIVE APPROACHES TO GROWTH IN THE SEMICONDUCTOR INDUSTRY, 1996, : 186 - 191
  • [10] Characterization of missing-poly defects in ion implantation in ULSI manufacturing
    Dunham, B
    Anundson, R
    Zhao, ZY
    [J]. CHARACTERIZATION AND METROLOGY FOR ULSI TECHNOLOGY, 2003, 683 : 278 - 283
12345