Pressure dependence of the interfacial polarization and negative activation volume for dielectric relaxation in heterogeneous systems

TL;DR

This study investigates how pressure influences interfacial polarization and dielectric relaxation in heterogeneous systems, revealing negative activation volumes and providing a theoretical explanation for these phenomena.

Contribution

The paper introduces a theoretical model within the effective medium approximation that predicts the negative activation volume in water-saturated polycrystalline materials.

Findings

Interfacial polarization shows increased relaxation frequency under pressure.

Negative activation volumes are confirmed in heterogeneous systems.

Theoretical predictions match experimental observations of activation volume magnitude.

Abstract

Negative activation volumes for dielectric relaxation are rarely reported in solid state physics and are limited to atomic scale processes. Broadband Dielectric Spectroscopy on heterogeneous systems, such as polycrystalline calcite and magnesite, hosting water in their porous spce, detectedintense dielectric relaxation mechanisms related to the interfacial polarization. The characteristic relaxation frequency increased uponhydrostatic compression, indicating that the activation volumes for relaxation are negative. However, a theoretical interpretation for the negative sign of the activation volume is lacking up to date. Within the frame of effective medium approximation for mesoscopic heterogeneous two phase solid - fluid systems, we investigate how the synergyof the pressure depedencies of polarization and electric charge transport, respectively, dictate the pressure dependence of interfacial polarization . predicting the value of the effective activation volume. Our theoretical approach succeeds in predicting the negative sign and magnitude of the activation volume in water saturated polycrystalline materials.