Self-suspended membrane for structural and elastic investigation in industrial applications

Self-suspended membrane for structural and elastic investigation in industrial applications

Responsable : Laurent Belliard
Contact : laurent.belliard@sorbonne-universite.fr
Tutelle : INSP / Sorbonne Université -Saint Gobain Recherche
Mots clés : Experimental, Nano Photo-Phononique, Stage M2, et Thèse proposée
Gratification : Oui
Page des stages de(s) l'équipe(s) : Acoustique et optique pour les nanosciences et le quantique
Description du stage

Stage en collaboration avec Saint-Gobain Research Paris

Scientific description:
Worldwide leader in light and sustainable construction, Saint-Gobain designs, manufactures and distributes materials and services for the construction and industrial markets.
Its integrated solutions for the renovation of public and private buildings, light construction and the decarbonization of construction and industry are developed through a continuous innovation process and provide sustainability and performance.
To answer these challenges, we must provide materials with complex structures. E.g., new functions are given to the glass by the deposition of thin films like in electrochromic glasses and in thermally insulating glasses. These solutions allow to reduce the energy consumption in buildings and vehicles thanks to saving in air conditioning and heating.
The investigative resources needed to study these thin films, with thicknesses of less than 50 nm, are often the prerogative of large academic research laboratories. This is the background to the collaboration with the Institut des NanoSciences de Paris.

The properties of these deposits targeted in this internship are those linked to elasticity and microstructure, which strongly condition their adhesion to glass and hence the functionalization of Saint-Gobain products.

To facilitate this type of study, an innovative approach is to develop these deposits in a self-suspended membrane geometry, in order to neglect the underlying substrate. In this context, we will attempt to elaborate such objects using nanostructuring processes in the INSP cleanroom.
The resulting membranes will be characterized at INSP using pump-probe methods enabling the generation of acoustic waves with frequencies up to a few hundred GHz allowing to obtain very good in-depth resolution. Complementary bulge-test measurements will be carried out at Saint-Gobain