Laser cleaning of silicon surfaces

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235_procspie_1998.pdf(5.19 MB)
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1998
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Schilling, Andreas
Yavaṣ, Oğuz
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urn:nbn:de:bsz:352-opus-28889
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10.1117/12.309495
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Laser Applications in Microelectronic and Optoelectronic Manufacturing III / Dubowski, Jan J.; Dyer, Peter E. (ed.). - SPIE, 1998. - (SPIE Proceedings ; 3274). - pp. 68-78
Abstract
The continuing trend towards miniaturization of integrated circuits requires increasing effots and new concepts to clean wafer surfaces from dust particles. We report here about our studies of the "steam laser cleaning" process first described by Tam and coworkers: In order to remove sub-micron particles from a surface, first a thin liquid layer is condensed onto the substrate from the gas phase, and is subsequently evaporated momentarily by irradiating the surface with a short laser pulse. We have investigated the nucleation and growth of gas bubbles in the liquid, by which the whole process is started, with optical techniques like light scattering and surface plasmon resonance spectroscopy. The experiments indicate that the temperature where nucleation sets in is surprisingly low, which facilitates the application of this phenomenon for cleaning purposes. On the basis of these results and in order to study the cleaning effect for the particularly interesting surface of silicon in a quantitative way, we have deposited well-characterized spherical polymer and silica particles of different diameters from several ten to hundred nanometers on commercial Si wafers and have studied systematically the cleaning efficiency of the explosive evaporation process. The results show that steam laser cleaning is a promising and suitable method for removing sub-micron particles from semiconductor surfaces.
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Subject (DDC)
530 Physics
Keywords
laser cleaning,bubble nucleation,superheating,pressure measurement,particle removal
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Optoelectronics and High-Power Lasers & Applications, San Jose, CA
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Cite This
ISO 690LEIDERER, Paul, Johannes BONEBERG, Mario MOSBACHER, Andreas SCHILLING, Oğuz YAVAṢ, 1998. Laser cleaning of silicon surfaces. Optoelectronics and High-Power Lasers & Applications. San Jose, CA. In: DUBOWSKI, Jan J., ed., Peter E. DYER, ed.. Laser Applications in Microelectronic and Optoelectronic Manufacturing III. SPIE, pp. 68-78. Available under: doi: 10.1117/12.309495
BibTex
@inproceedings{Leiderer1998-06-03Laser-5007,
  year={1998},
  doi={10.1117/12.309495},
  title={Laser cleaning of silicon surfaces},
  number={3274},
  publisher={SPIE},
  series={SPIE Proceedings},
  booktitle={Laser Applications in Microelectronic and Optoelectronic Manufacturing III},
  pages={68--78},
  editor={Dubowski, Jan J. and Dyer, Peter E.},
  author={Leiderer, Paul and Boneberg, Johannes and Mosbacher, Mario and Schilling, Andreas and Yavaṣ, Oğuz}
}
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