First-principles modeling of high-k gate dielectric materials

被引:37
|
作者
Cho, K [1 ]
机构
[1] Stanford Univ, Dept Mech Engn, Stanford, CA 94305 USA
来源
COMPUTATIONAL MATERIALS SCIENCE | 2002年 / 23卷 / 1-4期
关键词
high-k gate dielectric; first principles modeling; metal silicates; metal aluminates;
D O I
10.1016/S0927-0256(01)00209-9
中图分类号
T [工业技术];
学科分类号
08 ;
摘要
Materials problems of alternative high-k dielectric oxides for future metal-oxide-semiconductor field effect transistor (MOSFET) gate oxide application are examined from first-principles modeling perspective. We have analyzed the relationship between local atomic structure, and the corresponding ionic contributions to static dielectric constant for metal oxides. and the analysis shows the importance of stabilizing high oxygen coordination structures for metal atoms. Based on the local atomic structure analysis, metal silicates and aluminate are expected to provide a possible solution of continuously scaling dielectric constant ell above the of amorphous silica (epsilon(0) = 3.9) and alumina (epsilon(0) = 9). (C) 2002 Elsevier Science B.V. All rights reserved.
引用
收藏
页码:43 / 47
页数:5
相关论文
共 50 条
  • [21] Electronic structures of high-k transition metal silicates:: first-principles calculations
    Samantaray, CB
    Sim, H
    Hwang, H
    MICROELECTRONICS JOURNAL, 2004, 35 (08) : 655 - 658
  • [22] First-Principles Investigation of High-k Dielectrics for Non-Volatile Memories
    Pourtois, G.
    Sankaran, K.
    Radu, I.
    Degraeve, R.
    Zahid, M. B.
    Van Elshocht, S.
    Adelmann, C.
    De Gendt, S.
    Heyns, M. M.
    Wouters, D.
    Kittl, J. A.
    Jurczak, M.
    Rignanese, G. -M.
    Van Houdt, J.
    PHYSICS AND TECHNOLOGY OF HIGH-K MATERIALS 8, 2010, 33 (03): : 393 - 407
  • [23] First-principles simulations of the leakage current in metal-oxide-semiconductor structures caused by oxygen vacancies in HfO2 high-K gate dielectric
    Mao, L. F.
    Wang, Z. O.
    PHYSICA STATUS SOLIDI A-APPLICATIONS AND MATERIALS SCIENCE, 2008, 205 (01): : 199 - 203
  • [24] Challenges and opportunities in high-k gate dielectric technology
    Niwa, M
    Harada, Y
    Yamamoto, K
    Hayashi, S
    Mitsuhashi, R
    Eriguchi, K
    Kubota, M
    Hoshino, Y
    Kido, Y
    Kwong, DL
    RAPID THERMAL AND OTHER SHORT-TIME PROCESSING TECHNOLOGIES III, PROCEEDINGS, 2002, 2002 (11): : 99 - 115
  • [25] High-k polymer nanocomposites for gate dielectric applications
    Lu, Jiongxin
    Moon, Kyoung-Sik
    Wong, C. P.
    2007 12TH INTERNATIONAL SYMPOSIUM ON ADVANCED PACKAGING MATERIALS: PROCESSES, PROPERTIES, AND INTERFACES, 2007, : 80 - 84
  • [26] Characterization of High-k Gate Dielectric with Amorphous Nanostructure
    Ali Bahari
    Reza Gholipur
    Journal of Electronic Materials, 2013, 42 : 3529 - 3540
  • [27] Characterization of High-k Gate Dielectric with Amorphous Nanostructure
    Bahari, Ali
    Gholipur, Reza
    JOURNAL OF ELECTRONIC MATERIALS, 2013, 42 (12) : 3529 - 3540
  • [28] Theoretical analysis of high-k dielectric gate stacks
    Demkov, A. A.
    Sharia, O.
    Lee, J. K.
    MICROELECTRONIC ENGINEERING, 2007, 84 (9-10) : 2032 - 2034
  • [29] Characterization of high-k gate dielectric/silicon interfaces
    Miyazaki, S
    APPLIED SURFACE SCIENCE, 2002, 190 (1-4) : 66 - 74
  • [30] CHC degradation of strained devices based on SiON and high-k gate dielectric materials
    Amat, E.
    Rodriguez, R.
    Gonzalez, M. B.
    Martin-Martinez, J.
    Nafria, M.
    Aymerich, X.
    Verheyen, P.
    Simoen, E.
    MICROELECTRONIC ENGINEERING, 2011, 88 (07) : 1408 - 1411
12345