Propagating topological transformations in thin immiscible bilayer films

M. G. Hennessy; V. M. Burlakov; A. Münch; B. Wagner; A. Goriely

doi:10.1209/0295-5075/105/66001

Propagating topological transformations in thin immiscible bilayer films

M. G. Hennessy, V. M. Burlakov, A. Münch, B. Wagner, A. Goriely

Research output: Contribution to journal › Article (Academic Journal) › peer-review

4 Citations (Scopus)

Abstract

A physical mechanism for the topological transformation of a two-layer system confined by two substrates is proposed. Initially the two horizontal layers, A and B, are on top of each other, but upon a sufficiently large disturbance, they can rearrange themselves through a spontaneously propagating sectioning to create a sequence of vertical alternating domains ABABAB. This generic topological transformation could be used to control the morphology of fabricated nanocomposites by first creating metastable layered structures and then triggering their transformation. The generality is underscored by formulating conditions for this topological transformation in terms of the interface energies between phases and substrates. The theoretical estimate for the width of the domains is confirmed by simulations of a phase-field model and its thin-film/sharp-interface approximation.

Original language	English
Article number	66001
Journal	EPL
Volume	105
Issue number	6
DOIs	https://doi.org/10.1209/0295-5075/105/66001
Publication status	Published - Mar 2014

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title = "Propagating topological transformations in thin immiscible bilayer films",

abstract = "A physical mechanism for the topological transformation of a two-layer system confined by two substrates is proposed. Initially the two horizontal layers, A and B, are on top of each other, but upon a sufficiently large disturbance, they can rearrange themselves through a spontaneously propagating sectioning to create a sequence of vertical alternating domains ABABAB. This generic topological transformation could be used to control the morphology of fabricated nanocomposites by first creating metastable layered structures and then triggering their transformation. The generality is underscored by formulating conditions for this topological transformation in terms of the interface energies between phases and substrates. The theoretical estimate for the width of the domains is confirmed by simulations of a phase-field model and its thin-film/sharp-interface approximation.",

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T1 - Propagating topological transformations in thin immiscible bilayer films

AU - Hennessy, M. G.

AU - Burlakov, V. M.

AU - Münch, A.

AU - Wagner, B.

AU - Goriely, A.

PY - 2014/3

Y1 - 2014/3

N2 - A physical mechanism for the topological transformation of a two-layer system confined by two substrates is proposed. Initially the two horizontal layers, A and B, are on top of each other, but upon a sufficiently large disturbance, they can rearrange themselves through a spontaneously propagating sectioning to create a sequence of vertical alternating domains ABABAB. This generic topological transformation could be used to control the morphology of fabricated nanocomposites by first creating metastable layered structures and then triggering their transformation. The generality is underscored by formulating conditions for this topological transformation in terms of the interface energies between phases and substrates. The theoretical estimate for the width of the domains is confirmed by simulations of a phase-field model and its thin-film/sharp-interface approximation.

AB - A physical mechanism for the topological transformation of a two-layer system confined by two substrates is proposed. Initially the two horizontal layers, A and B, are on top of each other, but upon a sufficiently large disturbance, they can rearrange themselves through a spontaneously propagating sectioning to create a sequence of vertical alternating domains ABABAB. This generic topological transformation could be used to control the morphology of fabricated nanocomposites by first creating metastable layered structures and then triggering their transformation. The generality is underscored by formulating conditions for this topological transformation in terms of the interface energies between phases and substrates. The theoretical estimate for the width of the domains is confirmed by simulations of a phase-field model and its thin-film/sharp-interface approximation.

UR - https://www.scopus.com/pages/publications/84897434092

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DO - 10.1209/0295-5075/105/66001

M3 - Article (Academic Journal)

AN - SCOPUS:84897434092

SN - 0295-5075

VL - 105

JO - EPL

JF - EPL

IS - 6

M1 - 66001

ER -

Propagating topological transformations in thin immiscible bilayer films

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