High-aspect ratio nanopatterning via combined thermal scanning probe lithography and dry etching

Thermal scanning probe lithography is an emerging nanofabrication technique for rapid prototyping of arbitrary topographies in thermally sensitive resist. This feature, paired to the recent advances in dry plasma etching techniques, allows the fabrication of high-resolution nanopatterns in hard subs...

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Veröffentlicht in:	Microelectronic engineering 2017-08, Vol.180, p.20-24
Hauptverfasser:	Lisunova, Y., Spieser, M., Juttin, R.D.D., Holzner, F., Brugger, J.
Format:	Artikel
Sprache:	eng
Schlagworte:	2D and 3D nanopatterns Dry etching Etch selectivity Heat treatment High aspect ratio Lithography Nanofabrication Offset printing Plasma etching Poly(phthalaldehyde) Process parameters Rapid prototyping Scanning Silicon Silicon substrates Substrates Surface roughness Thermal scanning probe lithography Topography
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container_title	Microelectronic engineering
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creator	Lisunova, Y. Spieser, M. Juttin, R.D.D. Holzner, F. Brugger, J.
description	Thermal scanning probe lithography is an emerging nanofabrication technique for rapid prototyping of arbitrary topographies in thermally sensitive resist. This feature, paired to the recent advances in dry plasma etching techniques, allows the fabrication of high-resolution nanopatterns in hard substrates. Here, we investigate the key process parameters allowing the fabrication of high aspect ratio nanopatterns in silicon. By a combination of resist heat treatment, the use of a hard mask and optimized etch parameters during pattern transfer, we amplified the shallow resist patterns by a factor of 100 into the silicon substrate. Low surface roughness and vertical sidewalls are thereby maintained. We demonstrate the fabrication of 240nm wide lines and 4μm deep single crystal silicon patterns.
doi_str_mv	10.1016/j.mee.2017.04.006
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subjects	2D and 3D nanopatterns Dry etching Etch selectivity Heat treatment High aspect ratio Lithography Nanofabrication Offset printing Plasma etching Poly(phthalaldehyde) Process parameters Rapid prototyping Scanning Silicon Silicon substrates Substrates Surface roughness Thermal scanning probe lithography Topography
title	High-aspect ratio nanopatterning via combined thermal scanning probe lithography and dry etching
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