Experimental Evidence for the Pore Size Dependence of Elastic Properties in a Liquid Adsorbate Confined to Nanopores

Key Points

The modulus of liquid argon increases linearly with the inverse pore radius, indicating strong pore size dependence.
Longitudinal modulus measurements show significant variations across pore sizes from 1.8 to 12.8 nm, confirming theoretical predictions.
Ultrasonic study employed to analyze elastic properties of liquid argon in different pore sizes within porous glass.
Research highlights the crucial role of nanopore size in determining the elasticity of confined adsorbates, which may impact material design.

Abstract

The elasticity of adsorbates is relevant for many applications of porous materials. Theoretical studies predict a pronounced increase of elastic moduli for adsorbates under nanoconfinement, but an experimental confirmation is still missing. Here we present an ultrasonic study on the longitudinal modulus βAr,ads of liquid argon in porous glass samples with different pore radii between 1.8 and 12.8 nm. The analysis of the measured moduli of empty, β0, and filled samples, β, reveals that the modulus of the adsorbate, βAr,ads, increases linearly with the inverse pore radius, 1/rP, as predicted by theory.

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