Influence of elastic deformation of porous materials in adsorption-desorption process. A thermodynamic approach

TL;DR

This paper presents a thermodynamic model incorporating elastic deformation of porous materials during adsorption-desorption, revealing how elastic energy influences stability, hysteresis, and pore interaction in various porous solids.

Contribution

It introduces a thermodynamic approach that accounts for elastic deformation effects in adsorption processes, a factor neglected in previous models, applicable to all porous materials.

Findings

Elastic deformation causes hysteresis in adsorption-desorption cycles.

Elastic energy significantly affects the stability and energy barriers of pore filling and emptying.

Pore interactions are mediated through wall deformation, influencing adsorption behavior.

Abstract

It has been known for a long time that the adsorption and condensation of gas cause elastic deformation of the porous matrix. The reversible formation of an adsorbed film, which precedes capillary condensation, results in an extension of the porous material while, in the hysteresis region, the negative liquid pressures under the concave menisci contract the porous matrix. The elastic deformation exhibits an hysteresis loop in the same pressure region as the adsorption phenomenon. These deformations have been neglected in practically all the theoretical treatments of adsorption. We develop a thermodynamic approach which includes the elastic energy of the solid. This approach is generic to all porous materials. Thermodynamics of adsorption is directly connected to the elastic properties of the porous solid. We find that the variation of the surface free energy related to the elastic deformation is an important component of the total free energy. It is shown that the condensation branch represents the more stable states and that an energy barrier exists to evaporation which depends essentially on the elastic deformation. The pores interact through the deformation of the walls. Based on this interaction mechanism and on the shape of the scanning curves which are common to materials with interconnected pores such as porous glass or noninterconnected pores such as p+-type porous silicon and SBA-15, we propose a scenario for the filling and emptying of these porous materials.