Simulation of the Impedance Response of Materials with More Than One Electrical Path

R. A. Gerhardt [1], Y. Jin [1],
[1] Georgia Institute of Technology, Atlanta, GA, USA
Published in 2015

  1. Introduction

Polycrystalline single phase materials often display electrical properties that are a function of their grain size. Impedance spectroscopy, an alternating current technique is ideal for detecting the presence of more than one current path and has been used for many years[1,2]. However, it is proposed here that it may be possible to use concepts developed for two phase composites, to unravel the complexities of their electrical response as function of grain size and/or grain boundary thickness. The finite element model being used here was first developed to represent an ordered insulator-conductor composite with a segregated network microstructure [3].

  1. Use of COMSOL Multiphysics®

In this study, we used a finite element approach to solve the electric potential in the AC environments for an idealized two-phase microstructure as shown in Figure 1. The faceted grains represent the main material phase and the boundary region has finite thickness and distinct electrical properties that may or may not percolate with itself. The steps used include: (1) Selecting the AC/DC Module in the COMSOL Multiphysics® software, (version 4.4), (2) Defining the electrical properties inside the grains and the grain boundaries, (3) Solving and finding the electric field distributions and (4) Using postprocessing capabilities in the COMSOL software to determine the impedance response.

  1. Results

Figure 2 illustrates simulated equivalent circuit complex impedance spectra when the two electrical paths are in series [4]. It is clear that changes in the conductivity of the main grains may or may not be detected, depending on whether the grain boundaries are more or less conducting than the matrix grains.

Assuming a situation where the grain boundaries are more conducting than the matrix grains, FEA simulations revealed that if the grain boundaries are allowed to percolate, the complex impedance spectra may be dominated by the properties of the matrix grains or the grain boundaries. In order to evaluate these effects, percolated and unpercolated structures using the same grain size and grain boundary area were simulated. In Figure 3(a), it can be seen that unpercolated grain boundaries give rise to perfect semicircles as would be expected from a simplified equivalent circuit analysis of two parallel RC circuits in series. However, in Figure 3(b), it is clear that if the grain boundaries form a percolated path that both the matrix grain semicircle and the grain boundary semicircle undergo shape changes. Similar shape changes in the complex impedance are seen when the radius of the grains or grain boundaries is varied by several orders of magnitude while the grain boundary phase percolates (not shown).

  1. Conclusions

The FEA simulations have revealed that complex impedance semicircle shapes are very sensitive to the size and properties of the matrix grains and grain boundaries. Combining equivalent circuit and FEA analysis will be very powerful in helping to understand the behavior of complex heterogeneous materials, as well as for any material that is undergoing a phase change or any other process that can affect the behavior of the grain boundaries separately from the matrix grains.