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Atomic-beam alignment of inorganic materials for liquid-crystal displays

Author

Listed:
  • P. Chaudhari

    (IBM Watson Research Centre)

  • James Lacey

    (IBM Watson Research Centre)

  • James Doyle

    (IBM Watson Research Centre)

  • Eileen Galligan

    (IBM Watson Research Centre)

  • Shui-Chi Alan Lien

    (IBM Watson Research Centre)

  • Alesandro Callegari

    (IBM Watson Research Centre)

  • Gareth Hougham

    (IBM Watson Research Centre)

  • Norton D. Lang

    (IBM Watson Research Centre)

  • Paul S. Andry

    (IBM Watson Research Centre)

  • Richard John

    (IBM Watson Research Centre)

  • Kei-Hsuing Yang

    (IBM Watson Research Centre)

  • Minhua Lu

    (IBM Watson Research Centre)

  • Chen Cai

    (IBM Watson Research Centre)

  • James Speidell

    (IBM Watson Research Centre)

  • Sampath Purushothaman

    (IBM Watson Research Centre)

  • John Ritsko

    (IBM Watson Research Centre)

  • Mahesh Samant

    (IBM Almaden Research Centre)

  • Joachim Stöhr

    (IBM Almaden Research Centre)

  • Yoshiki Nakagawa

    (IBM Japan Ltd, Display Business Unit)

  • Yoshimine Katoh

    (IBM Japan Ltd, Display Business Unit)

  • Yukito Saitoh

    (IBM Japan Ltd, Display Business Unit)

  • Kazumi Sakai

    (IBM Japan Ltd, Display Business Unit)

  • Hiroyuki Satoh

    (IBM Japan Ltd, Display Business Unit)

  • Shuichi Odahara

    (IBM Japan Ltd, Display Business Unit)

  • Hiroki Nakano

    (IBM Japan Ltd, Advanced Manufacturing Engineering)

  • Johji Nakagaki

    (IBM Japan Ltd, Advanced Manufacturing Engineering)

  • Yasuhiko Shiota

    (IBM Japan Ltd, Advanced Manufacturing Engineering)

Abstract

The technique used to align liquid crystals—rubbing the surface of a substrate on which a liquid crystal is subsequently deposited1,2,3—has been perfected by the multibillion-dollar liquid-crystal display industry. However, it is widely recognized that a non-contact alignment technique would be highly desirable for future generations of large, high-resolution liquid-crystal displays. A number of alternative alignment techniques have been reported4,5,6,7, but none of these have so far been implemented in large-scale manufacturing. Here, we report a non-contact alignment process, which uses low-energy ion beams impinging at a glancing angle on amorphous inorganic films, such as diamond-like carbon. Using this approach, we have produced both laptop and desktop displays in pilot-line manufacturing, and found that displays of higher quality and reliability could be made at a lower cost than the rubbing technique. The mechanism of alignment is explained by adopting a random network model of atomic arrangement in the inorganic films. Order is induced by exposure to an ion beam because unfavourably oriented rings of atoms are selectively destroyed. The planes of the remaining rings are predominantly parallel to the direction of the ion beam.

Suggested Citation

  • P. Chaudhari & James Lacey & James Doyle & Eileen Galligan & Shui-Chi Alan Lien & Alesandro Callegari & Gareth Hougham & Norton D. Lang & Paul S. Andry & Richard John & Kei-Hsuing Yang & Minhua Lu & C, 2001. "Atomic-beam alignment of inorganic materials for liquid-crystal displays," Nature, Nature, vol. 411(6833), pages 56-59, May.
    • Handle: RePEc:nat:nature:v:411:y:2001:i:6833:d:10.1038_35075021
    DOI: 10.1038/35075021
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