Anisotropic dewetting of ion irradiated solid films

Experiments of irradiation with 30keV Ga ions were conducted on ultrathin chromium films on rippled silicon substrates. The evolution of their surface morphology, as detected by real time scanning electron microscopy, shows an apparent differential sputtering yield for regions of positive and negati...

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Veröffentlicht in:	Nuclear instruments & methods in physics research. Section B, Beam interactions with materials and atoms Beam interactions with materials and atoms, 2013-11, Vol.315, p.244-247
Hauptverfasser:	Repetto, L., Šetina Batič, B., Firpo, G., Piano, E., Valbusa, U.
Format:	Artikel
Sprache:	eng
Schlagworte:	Anisotropy Chromium Curvature Dewetting Focused ion beam Ions Irradiation Mathematical analysis Mathematical models Self-organization Sputtering Thin films
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container_title	Nuclear instruments & methods in physics research. Section B, Beam interactions with materials and atoms
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creator	Repetto, L. Šetina Batič, B. Firpo, G. Piano, E. Valbusa, U.
description	Experiments of irradiation with 30keV Ga ions were conducted on ultrathin chromium films on rippled silicon substrates. The evolution of their surface morphology, as detected by real time scanning electron microscopy, shows an apparent differential sputtering yield for regions of positive and negative curvature which is in contrast with the standard theory for curvature depending sputtering yield. In particular, at the end of the irradiation process, chromium wires are left in the valleys of the substrate. This result was explained in terms of local melting caused by the ion impact and of a process of dewetting under the concurring actions of surface tension and Van der Waals forces while ion sputtering is active. The interpretation of the reported experimental results are fully supported by numeric simulations implementing the same continuum model used to explain ion induced spinodal dewetting. This hierarchical self-organization process breaks the symmetry of previously demonstrated ion induced dewetting, making possible to create new structures by using the same fundamental effects.
doi_str_mv	10.1016/j.nimb.2013.04.010
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The evolution of their surface morphology, as detected by real time scanning electron microscopy, shows an apparent differential sputtering yield for regions of positive and negative curvature which is in contrast with the standard theory for curvature depending sputtering yield. In particular, at the end of the irradiation process, chromium wires are left in the valleys of the substrate. This result was explained in terms of local melting caused by the ion impact and of a process of dewetting under the concurring actions of surface tension and Van der Waals forces while ion sputtering is active. The interpretation of the reported experimental results are fully supported by numeric simulations implementing the same continuum model used to explain ion induced spinodal dewetting. 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The evolution of their surface morphology, as detected by real time scanning electron microscopy, shows an apparent differential sputtering yield for regions of positive and negative curvature which is in contrast with the standard theory for curvature depending sputtering yield. In particular, at the end of the irradiation process, chromium wires are left in the valleys of the substrate. This result was explained in terms of local melting caused by the ion impact and of a process of dewetting under the concurring actions of surface tension and Van der Waals forces while ion sputtering is active. The interpretation of the reported experimental results are fully supported by numeric simulations implementing the same continuum model used to explain ion induced spinodal dewetting. 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subjects	Anisotropy Chromium Curvature Dewetting Focused ion beam Ions Irradiation Mathematical analysis Mathematical models Self-organization Sputtering Thin films
title	Anisotropic dewetting of ion irradiated solid films
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