https://sam.ensam.eu:443 The DSpace digital repository system captures, stores, indexes, preserves, and distributes digital research material. Sun, 12 Apr 2026 20:17:33 GMT 2026-04-12T20:17:33Z http://hdl.handle.net/10985/9696 A multilayer model for describing hardness variations of aged porous silicon low-dielectric-constant thin films RAHMOUN, Khadidja; IOST, Alain; KERYVIN, Vincent; GUILLEMOT, Gildas; CHABANE, Sari This 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 oxidized cap layer, but not on the mechanical properties of the substrate, even for indentation depths slightly lower than the film's thickness. One of the authors (K.R.) wants to thank Pr. Lazhar Haji for her proposal of a research stay at Laboratoire d'Optronique, CNRS-UMR FOTON 6082, Université de Rennes 1, France. The authors also wish to thank Dr. M. Gendouz (Laboratoire d'Optronique, CNRS-UMR FOTON 6082, Université de Rennes 1), J. Le Lannic (CMEBA, Université de Rennes 1), Pr. C. Mathieu (CCML Université d'Artois, Faculté Jean Perrin de Lens, France), and V. Hague (ENSAM Lille, France) respectively for their help with sample preparation, HR SEM or SEM observations and assistance as regards English. Thu, 01 Jan 2009 00:00:00 GMT http://hdl.handle.net/10985/9696 2009-01-01T00:00:00Z RAHMOUN, Khadidja IOST, Alain KERYVIN, Vincent GUILLEMOT, Gildas CHABANE, Sari This 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 oxidized cap layer, but not on the mechanical properties of the substrate, even for indentation depths slightly lower than the film's thickness. http://hdl.handle.net/10985/9703 Vickers Microhardness of Oxidized and Nonoxidized Porous Silicon RAHMOUN, Khadidja; IOST, Alain; KERYVIN, Vincent; GUILLEMOT, Gildas; SANGLEBOEUF, Jean-Christophe; GUENDOUZ, Mohamed; HAJI, Lazhar In this work we present our recent investigation on characterizing mechanical properties of porous silicon (PS) by using instrumented micro-indentation. Hardness and elastic modulus for oxidized and nonoxidized PS were measured. Experimental results revealed that hardness and elastic modulus are significantly lower than that of silicon substrate and decrease with increasing porosities. After oxidation an increase of the hardness and elastic modulus were observed. The task of stabilization of PS mechanical parameters can be solved with the help of oxidation. Thu, 01 Jan 2015 00:00:00 GMT http://hdl.handle.net/10985/9703 2015-01-01T00:00:00Z RAHMOUN, Khadidja IOST, Alain KERYVIN, Vincent GUILLEMOT, Gildas SANGLEBOEUF, Jean-Christophe GUENDOUZ, Mohamed HAJI, Lazhar In this work we present our recent investigation on characterizing mechanical properties of porous silicon (PS) by using instrumented micro-indentation. Hardness and elastic modulus for oxidized and nonoxidized PS were measured. Experimental results revealed that hardness and elastic modulus are significantly lower than that of silicon substrate and decrease with increasing porosities. After oxidation an increase of the hardness and elastic modulus were observed. The task of stabilization of PS mechanical parameters can be solved with the help of oxidation.