Non-local linear stability of ion beam eroded surfaces

► Extension of Bradley-Harper theory (BHT) avoiding gradient expansions. ► Extension of BHT including ion-induced surface mass redistribution. ► More complex scenarios of pattern formation than in BHT, including both type I and type II instabilities. ► Ion-beam induced pattern formation does not nee...

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Bibliographic Details
Published in:Applied surface science 2012-02, Vol.258 (9), p.4179-4185
Main Authors: More, S.N., Kree, R.
Format: Article
Language:English
Subjects:
Atomic, molecular, and ion beam impact and interactions with surfaces
Bifurcation
Bifurcations
Cascades
Collision dynamics
Condensed matter: electronic structure, electrical, magnetic, and optical properties
Continuum theory
Continuums
Craters
Cross-disciplinary physics: materials science
rheology
Electron and ion emission by liquids and solids
impact phenomena
Exact sciences and technology
Formations
Impact phenomena (including electron spectra and sputtering)
Ion beam erosion
Materials science
Mathematical models
Methods of nanofabrication
Nanoscale pattern formation
Pattern formation
Physics
Si surface
Sputtering
Stability analysis
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Summary:► Extension of Bradley-Harper theory (BHT) avoiding gradient expansions. ► Extension of BHT including ion-induced surface mass redistribution. ► More complex scenarios of pattern formation than in BHT, including both type I and type II instabilities. ► Ion-beam induced pattern formation does not need erosion. ► Bifurcation scenarios depend sensitively upon statistical shapes of collision cascades. Continuum theories of spontaneous pattern formation at solid surfaces during ion irradiation exist in many variants, but all of them are based upon low order gradient expansions of an underlying non-local theory and are formulated as partial differential equations. Here we reconsider the non-local theory based upon a simple Gaussian erosive crater function of Sigmund's theory of sputtering, which is also a basic ingredient of most of the existing continuum theories. We keep the full non-locality of the crater function in a linear stability analysis of a flat surface. Without gradient expansion the evolution of the height profile is governed by an integral equation. We show that low order gradient expansions may be misleading and that the bifurcation scenarios become significantly more complex, if the non-locality is taken into account. In a second step, we extend our analysis and include mass redistribution due to ion-induced drift currents of collision cascade atoms. The model is based upon results from kinetic theory and uses a simple phenomenology. Both erosion and mass redistribution share the same non-local features, as they are both caused by the collision cascade. If mass redistribution is the dominant pattern forming mechanism, we show that the resulting bifurcation scenarios may provide explanations for many of the recent, seemingly contradictory experimental results of pattern formation on Si surfaces.
ISSN:0169-4332
1873-5584
DOI:10.1016/j.apsusc.2011.10.015