Khadidja Rahmoun scite author profile

International audienceThis paper reports on the micro-instrumented indentation of a porous silicon structure obtained by anodization of a highly p(+)-doped (100) silicon substrate aged over 1 week. The three-layer structure obtained consists of oxidized porous silicon (cap-layer), porous silicon (inner-layer) and silicon substrate. The hardness curve has the typical "U shape" of low-dielectric-constant films when the indentation depth rises: the early decrease in hardness, due to the soft inner layer, is followed by an increase, due to the hard substrate. A multilayer model is developed to account for hardness variation with respect to the applied load. This model considers the crumbling of the cap-layer and of the inner porous structure. As a result, it is shown that considering the minima in the U shape gives an over-estimated value when it comes to assessing the coating hardness. in our experiment, this minimum depends on both the hardness and the thickness of the but not on the mechanical properties of the substrate, even for indentation depths slightly oxidized cap layer, lower than the film's thickness. (C) 2009 Elsevier B.V. All rights reserved

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Mechanical properties of porous silicon and oxidized porous silicon by nanoindentation technique

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Montagne

Rahmoun

et al. 2018

Materials Science and Engineering: A

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Exploring N3 ruthenium dye adsorption onto ZnTiO3 (101) and (110) surfaces for dye sensitized solar cell applications: Full computational study

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Cheknane

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Materials Today Energy

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Investigation of triphenylamine-based sensitizer characteristics and adsorption behavior onto ZnTiO3 perovskite (1 0 1) surfaces for dye-sensitized solar cells using first-principle calculation

et al. 2020

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Effect of titanium dioxide nanoparticles on polymer network formation

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et al. 2017

Spectroscopy Letters

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