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The electronic structure at the atomic scale of ultrathin gate oxides

Author

Listed:
  • D. A. Muller

    (Bell Laboratories, Lucent Technologies)

  • T. Sorsch

    (Bell Laboratories, Lucent Technologies)

  • S. Moccio

    (Bell Laboratories, Lucent Technologies)

  • F. H. Baumann

    (Bell Laboratories, Lucent Technologies)

  • K. Evans-Lutterodt

    (Bell Laboratories, Lucent Technologies)

  • G. Timp

    (Bell Laboratories, Lucent Technologies)

Abstract

The narrowest feature on present-day integrated circuits is the gate oxide—the thin dielectric layer that forms the basis of field-effect device structures. Silicon dioxide is the dielectric of choice and, if present miniaturization trends continue, the projected oxide thickness by 2012 will be less than one nanometre, or about five silicon atoms across1. At least two of those five atoms will be at the silicon–oxide interfaces, and so will have very different electrical and optical properties from the desired bulk oxide, while constituting a significant fraction of the dielectric layer. Here we use electron-energy-loss spectroscopy in a scanning transmission electron microscope to measure the chemical composition and electronic structure, at the atomic scale, across gate oxides as thin as one nanometre. We are able to resolve the interfacial states that result from the spillover of the silicon conduction-band wavefunctions into the oxide. The spatial extent of these states places a fundamental limit of 0.7 nm (four silicon atoms across) on the thinnest usable silicon dioxide gate dielectric. And for present-day oxide growth techniques, interface roughness will raise this limit to 1.2 nm.

Suggested Citation

  • D. A. Muller & T. Sorsch & S. Moccio & F. H. Baumann & K. Evans-Lutterodt & G. Timp, 1999. "The electronic structure at the atomic scale of ultrathin gate oxides," Nature, Nature, vol. 399(6738), pages 758-761, June.
  • Handle: RePEc:nat:nature:v:399:y:1999:i:6738:d:10.1038_21602
    DOI: 10.1038/21602
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    Cited by:

    1. Zheyi Lu & Yang Chen & Weiqi Dang & Lingan Kong & Quanyang Tao & Likuan Ma & Donglin Lu & Liting Liu & Wanying Li & Zhiwei Li & Xiao Liu & Yiliu Wang & Xidong Duan & Lei Liao & Yuan Liu, 2023. "Wafer-scale high-κ dielectrics for two-dimensional circuits via van der Waals integration," Nature Communications, Nature, vol. 14(1), pages 1-8, December.
    2. Jiabiao Chen & Zhaochao Liu & Xinyue Dong & Zhansheng Gao & Yuxuan Lin & Yuyu He & Yingnan Duan & Tonghuai Cheng & Zhengyang Zhou & Huixia Fu & Feng Luo & Jinxiong Wu, 2023. "Vertically grown ultrathin Bi2SiO5 as high-κ single-crystalline gate dielectric," Nature Communications, Nature, vol. 14(1), pages 1-10, December.

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