Study of Model Assisted Rule Base SRAF for Random Contact

被引:1
|
作者
Moon, James [1 ]
Nam, Byoung-Sub [1 ]
Kim, Cheol-Kyun [1 ]
Yun, Hyong-Sun [1 ]
Lee, Ji-Young [2 ]
Yim, Donggyu [1 ]
Park, Sung-Ki [1 ]
机构
[1] Hynix Semicond Inc, Memory Res & Dev Div, San 136-1 Ami Ri, Icheon Si 467701, Kyungki Do, South Korea
[2] Mentor Graph Corp, Seoul 135729, South Korea
来源
OPTICAL MICROLITHOGRAPHY XXIV | 2011年 / 7973卷
关键词
Photo Lithography; Mask; OPC; RET; SRAF; ILT; CONTACT;
D O I
10.1117/12.879201
中图分类号
O43 [光学];
学科分类号
070207 ; 0803 ;
摘要
In this paper, we will evaluate model assisted rule base SRAF. Model assisted rule base SRAF combines the advantage of both model based SRAF and rule base SRAF to ensure high process margin without the mask making difficulty with stable wafer output. Model will assist in generating a common rule for rule based SRAF. Method to extract the rule from the models will first be discussed. Model assisted rule based SRAF will be applied to 3Xnm DRAM contact. Evaluation and analysis of the simulated and actual wafer result will be discussed. Our wafer result showed that by applying Model assisted rule based SRAF showed nearly equal performance to models based SRAF with clearly better stability and mask fabrication feasibility.
引用
收藏
页数:9
相关论文
共 50 条
  • [1] Model-based OPC for node random size contact hole with SRAF
    Huang, C. W.
    Chang, Y. Y.
    Yeh, L. S.
    Liao, H. Y.
    Shih, C. L.
    Lin, J. P.
    OPTICAL MICROLITHOGRAPHY XIX, PTS 1-3, 2006, 6154 : U2115 - U2119
  • [2] Impact of Illumination on Model -Based SRAF Placement for Contact Patterning
    Sturtevant, John L.
    Jayaram, Srividya
    El-Sewefy, Omar
    Dave, Aasutosh
    LaCour, Pat
    OPTICAL MICROLITHOGRAPHY XXIII, 2010, 7640
  • [3] Model base SRAF insertion check with OPC verify tools
    Hung, Chi-Yuan
    Deng, Zexi
    Gao, Gensheng
    Zhang, Liguo
    Liu, Qingwei
    PHOTOMASK AND NEXT GENERATION LITHOGRAPHY MASK TECHNOLOGY XIII, PTS 1 AND 2, 2006, 6283
  • [4] Study of SRAF placement for contact at 45 nm and 32 nm node
    Farys, V.
    Robert, F.
    Martinelli, C.
    Trouiller, Y.
    Sundermann, F.
    Gardin, C.
    Planchot, J.
    Kerrien, G.
    Vautrin, F.
    Saied, M.
    Yesilada, E.
    Foussadier, F.
    Villaret, A.
    Perraud, L.
    Vandewalle, B.
    Le Denmat, J. C.
    Top, M. K.
    OPTICAL MICROLITHOGRAPHY XXI, PTS 1-3, 2008, 6924
  • [5] Model-assisted template extraction SRAF application to contact holes patterns in high-end flash memory device fabrication
    Seoud, Ahmed
    Kim, Juhwan
    Ma, Yuansheng
    Jayaram, Srividya
    Hong, Le
    Chae, Gyu-Yeol
    Lee, Jeong-Woo
    Park, Dae-Jin
    Yune, Hyoung-Soon
    Oh, Se-Young
    Park, Chan-Ha
    OPTICAL MICROLITHOGRAPHY XXXI, 2018, 10587
  • [6] 2D SRAF Rule Extraction for Fast Application Based on Model-based Results
    Dai, Yaoxuan
    Su, Xiaojing
    Gao, Pengzheng
    Wei, Yayi
    Wang, Yanrong
    Zhang, Jing
    Yan, Jiang
    PHOTOMASK TECHNOLOGY 2018, 2018, 10810
  • [7] A random rule model of surface growth
    Mello, Bernardo A.
    PHYSICA A-STATISTICAL MECHANICS AND ITS APPLICATIONS, 2015, 419 : 762 - 767
  • [8] A Belief Rule Base Considering Random Variables of Adaptive Membership Functions
    Han, Peng
    Huang, Zhiqiu
    Li, Weiwei
    He, Wei
    Cao, You
    IEEE TRANSACTIONS ON INSTRUMENTATION AND MEASUREMENT, 2025, 74
  • [9] A Study of the Variability in Contact Resistive Random Access Memory by Stochastic Vacancy Model
    Kao, Yun-Feng
    Zhuang, Wei Cheng
    Lin, Chrong-Jung
    King, Ya-Chin
    NANOSCALE RESEARCH LETTERS, 2018, 13
  • [10] A Study of the Variability in Contact Resistive Random Access Memory by Stochastic Vacancy Model
    Yun-Feng Kao
    Wei Cheng Zhuang
    Chrong-Jung Lin
    Ya-Chin King
    Nanoscale Research Letters, 2018, 13
12345