Morphology evolution of thermally annealed polycrystalline thin films

A. González-González; G. M. Alonzo-Medina; A. I. Oliva; C. Polop; J. L. Sacedón; E. Vasco

doi:10.1103/PhysRevB.84.155450

Morphology evolution of thermally annealed polycrystalline thin films

A. González-González, G. M. Alonzo-Medina, A. I. Oliva, C. Polop, J. L. Sacedón, E. Vasco

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

25 Scopus citations

Abstract

Investigation of the morphology evolution of annealed polycrystalline Au(111) films by atomic force microscopy and x-ray diffraction leads to a continuous model that correlates such an evolution to local interactions between grains triggering different mechanisms of stress accommodation (grain zipping and shear strain) and relaxation (gap filling and grain rotation). The model takes into consideration findings concerning the in-plane reorientation of the grains during the coalescence to provide a comprehensive picture of the grain-size dependence of the interactions (underlying the origin of the growth stress in polycrystalline systems); and in particular it sheds light on the postcoalescence compressive stress as a consequence of the kinetic limitations for the reorientation of larger surface structures.

Original language	English
Article number	155450
Journal	Physical Review B - Condensed Matter and Materials Physics
Volume	84
Issue number	15
DOIs	https://doi.org/10.1103/PhysRevB.84.155450
State	Published - 31 Oct 2011
Externally published	Yes

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title = "Morphology evolution of thermally annealed polycrystalline thin films",

abstract = "Investigation of the morphology evolution of annealed polycrystalline Au(111) films by atomic force microscopy and x-ray diffraction leads to a continuous model that correlates such an evolution to local interactions between grains triggering different mechanisms of stress accommodation (grain zipping and shear strain) and relaxation (gap filling and grain rotation). The model takes into consideration findings concerning the in-plane reorientation of the grains during the coalescence to provide a comprehensive picture of the grain-size dependence of the interactions (underlying the origin of the growth stress in polycrystalline systems); and in particular it sheds light on the postcoalescence compressive stress as a consequence of the kinetic limitations for the reorientation of larger surface structures.",

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AU - González-González, A.

AU - Alonzo-Medina, G. M.

AU - Oliva, A. I.

AU - Polop, C.

AU - Sacedón, J. L.

AU - Vasco, E.

PY - 2011/10/31

Y1 - 2011/10/31

N2 - Investigation of the morphology evolution of annealed polycrystalline Au(111) films by atomic force microscopy and x-ray diffraction leads to a continuous model that correlates such an evolution to local interactions between grains triggering different mechanisms of stress accommodation (grain zipping and shear strain) and relaxation (gap filling and grain rotation). The model takes into consideration findings concerning the in-plane reorientation of the grains during the coalescence to provide a comprehensive picture of the grain-size dependence of the interactions (underlying the origin of the growth stress in polycrystalline systems); and in particular it sheds light on the postcoalescence compressive stress as a consequence of the kinetic limitations for the reorientation of larger surface structures.

AB - Investigation of the morphology evolution of annealed polycrystalline Au(111) films by atomic force microscopy and x-ray diffraction leads to a continuous model that correlates such an evolution to local interactions between grains triggering different mechanisms of stress accommodation (grain zipping and shear strain) and relaxation (gap filling and grain rotation). The model takes into consideration findings concerning the in-plane reorientation of the grains during the coalescence to provide a comprehensive picture of the grain-size dependence of the interactions (underlying the origin of the growth stress in polycrystalline systems); and in particular it sheds light on the postcoalescence compressive stress as a consequence of the kinetic limitations for the reorientation of larger surface structures.

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JO - Physical Review B - Condensed Matter and Materials Physics

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Morphology evolution of thermally annealed polycrystalline thin films

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