Influence of Elastic Strains on the Adsorption Process in Porous Materials: An experimental Approach

Article, Preprint English OPEN
Grosman , Annie ; Ortega , Camille (2009)
  • Publisher: American Chemical Society
  • Related identifiers: doi: 10.1016/j.apsusc.2009.12.098, doi: 10.1021/la9005955
  • Subject: Gas Adsorption | [ PHYS.COND.CM-GEN ] Physics [physics]/Condensed Matter [cond-mat]/Other [cond-mat.other] | Elastic Strains | Capillary Condensation | Condensed Matter - Other Condensed Matter | Porous Materials | Condensed Matter - Soft Condensed Matter
    mesheuropmc: technology, industry, and agriculture

International audience; The experimental results presented in this paper show the influence of the elastic deformation of porous solids on the adsorption process. With p+-type porous silicon formed on highly boron doped (100) Si single crystal, we can make identical porous layers, either supported by or detached from the substrate. The pores are perpendicular to the substrate. The adsorption isotherms corresponding to these two layers are distinct. In the region preceding capillary condensation, the adsorbed amount is lower for the membrane than for the supported layer and the hysteresis loop is observed at higher pressure. We attribute this phenomenon to different elastic strains undergone by the two layers during the adsorption process. For the supported layer, the planes perpendicular to the substrate are constrained to have the same interatomic spacing as that of the substrate so that the elastic deformation is unilateral, at an atomic scale, and along the pore axis. When the substrate is removed, tridimensional deformations occur and the porous system can find a new configuration for the solid atoms which decreases the free energy of the system adsorbate-solid. This results in a decrease of the adsorbed amount and to an increase of the condensation pressure. The isotherms for the supported porous layers shift towards that of the membrane when the layer thickness is increased from 30 to 100 microns. This is due to the relaxation of the stress exerted by the substrate as a result of the breaking of Si-Si bonds at the interface between the substrate and the porous layer. The membrane is the relaxed state of the supported layer.
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