Investigation of the dynamics of a percolation transition under rapid compression of a nanoporous body-nonwetting liquid system

TLDR: In this paper, the authors studied the dynamics of infiltration of a hydrophobic nanoporous body with a nonwetting liquid under rapid compression and found that the infiltration begins and occurs at a new constant pressure independent of the compression energy and viscosity of the liquid.

Abstract: The dynamics of infiltration of a nanoporous body with a nonwetting liquid under rapid compression is studied experimentally and theoretically Experiments are carried out on systems formed by a hydrophobic nanoporous body Libersorb 23, water, and an aqueous solution of CaCl2 at a compression rate of $$ \dot p $$ ≥ 104 atm/s It is found that the infiltration begins and occurs at a new constant pressure independent of the compression energy and viscosity of the liquid The time of infiltration and the filled volume increase with the compression energy A model of infiltration of a nanoporous body with a nonwetting liquid is constructed; using this model, infiltration is described as a spatially nonuniform process with the help of distribution functions for clusters formed by pores accessible to infiltration and filled ones On the basis of the proposed system of kinetic equations for these distribution functions, it is shown that under rapid compression, the infiltration process must occur at a constant pressure p c whose value is controlled by a new infiltration threshold θ c = 028 for the fraction of accessible pores, which is higher than percolation threshold θ c0 = 018 Quantity θ c is a universal characteristic of porous bodies In the range θ c0 < θ < θ c , infiltration of the porous body should not be observed It is shown that the solution to the system of kinetic equations leads to a nonlinear response by the medium to an external action (rapid compression), which means the compensation of this action by percolation of the liquid from clusters of filled pores of finite size to an infinitely large cluster of accessible but unfilled pores As a result of such compensation, infiltration is independent of the viscosity of the liquid It is found that all experimental results can be described quantitatively in the proposed model