Effective permittivity of compacted granular materials: Effects of interfacial polarization and pore-filling fluids

Effective permittivity of compacted granular materials: Effects of interfacial polarization and pore-filling fluids

Interfacial polarization dominates the permittivity spectra of heterogeneous granular materials for the intermediate frequency range (i.e., from kHz to MHz). In this study, we examine the corresponding dielectric responses of compacted glass sphere packings saturated with pore-filling fluids under v...

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Bibliographic Details
Main Authors: Xu Wang, Chongpu Zhai, Yixiang Gan
Format: Article
Language:English
Published: Elsevier 2024-11-01
Series:Theoretical and Applied Mechanics Letters
Subjects:
Interfacial polarization
Volumetric compression
Packing structure
Pore deformation
Artificial neuron network
Online Access:http://www.sciencedirect.com/science/article/pii/S2095034924000369
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Summary:Interfacial polarization dominates the permittivity spectra of heterogeneous granular materials for the intermediate frequency range (i.e., from kHz to MHz). In this study, we examine the corresponding dielectric responses of compacted glass sphere packings saturated with pore-filling fluids under various compressive stresses. The effective permittivity spectra are observed to exhibit consistently a plateau-to-plateau drop, described by low-frequency permittivity, characteristic frequency, and high-frequency permittivity. The permittivity spectra under different compressive levels are found to be influenced by the packing structure, compressive stress, and electrical property contrasts between solid and fluid (specifically permittivity and conductivity). For considered measurement conditions, the variation of packing structure and its associated porosity is found to be more significant than the stress evolution in controlling the interfacial polarization, thus the permittivity spectra, as supported by analytical and numerical results for unit cells. Furthermore, to gain a general rule for dielectric responses for saturated granular materials, we train multi-layer artificial neural network (ANN) models based on a series of simulations for unit cells with various structures, stresses, and electrical and dielectric properties. The predictions with two-layer ANN agree well with experimental measurements, presenting errors smaller than 5% for both low-frequency and high-frequency permittivity. This study offers an effective predicting approach for the dielectric behaviour of heterogeneous and multiphase materials.
ISSN:2095-0349

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