Diffuse-interface model for nanopatterning induced by self-sustained ion-etch masking

S. Le Roy; E. Søndergård; I. S. Nerbø; M. Kildemo; M. Plapp

doi:10.1103/PhysRevB.81.161401

Diffuse-interface model for nanopatterning induced by self-sustained ion-etch masking

S. Le Roy
, E. Søndergård
, I. S. Nerbø
, M. Kildemo
, M. Plapp

Research output: Contribution to journal › Article › peer-review

Abstract

We construct a simple phenomenological diffuse-interface model for composition-induced nanopatterning during ion sputtering of alloys. In simulations, this model reproduces without difficulties the high-aspect-ratio structures and tilted pillars observed in experiments. We investigate the time evolution of the pillar height, both by simulations and by in situ ellipsometry. The analysis of the simulation results yields a good understanding of the transitions between different growth regimes and supports the role of segregation in the pattern-formation process.

Original language	English
Article number	161401
Journal	Physical Review B - Condensed Matter and Materials Physics
Volume	81
Issue number	16
DOIs	https://doi.org/10.1103/PhysRevB.81.161401
Publication status	Published - 1 Apr 2010

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10.1103/PhysRevB.81.161401

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abstract = "We construct a simple phenomenological diffuse-interface model for composition-induced nanopatterning during ion sputtering of alloys. In simulations, this model reproduces without difficulties the high-aspect-ratio structures and tilted pillars observed in experiments. We investigate the time evolution of the pillar height, both by simulations and by in situ ellipsometry. The analysis of the simulation results yields a good understanding of the transitions between different growth regimes and supports the role of segregation in the pattern-formation process.",

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AU - Søndergård, E.

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AU - Kildemo, M.

AU - Plapp, M.

PY - 2010/4/1

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N2 - We construct a simple phenomenological diffuse-interface model for composition-induced nanopatterning during ion sputtering of alloys. In simulations, this model reproduces without difficulties the high-aspect-ratio structures and tilted pillars observed in experiments. We investigate the time evolution of the pillar height, both by simulations and by in situ ellipsometry. The analysis of the simulation results yields a good understanding of the transitions between different growth regimes and supports the role of segregation in the pattern-formation process.

AB - We construct a simple phenomenological diffuse-interface model for composition-induced nanopatterning during ion sputtering of alloys. In simulations, this model reproduces without difficulties the high-aspect-ratio structures and tilted pillars observed in experiments. We investigate the time evolution of the pillar height, both by simulations and by in situ ellipsometry. The analysis of the simulation results yields a good understanding of the transitions between different growth regimes and supports the role of segregation in the pattern-formation process.

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DO - 10.1103/PhysRevB.81.161401

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Diffuse-interface model for nanopatterning induced by self-sustained ion-etch masking

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