Coherent Potential Approximation as a Voltage Probe

TL;DR

This paper reinterprets the coherent potential approximation (CPA) within the Landauer-Büttiker framework, linking it to the voltage-probe model to analyze local chemical potentials and interface resistances in disordered layered systems.

Contribution

It introduces a novel interpretation of single-site CPA as a voltage-probe model, enabling detailed analysis of chemical potential profiles in disordered conductors.

Findings

CPA can be viewed as a voltage-probe model for phase-breaking scattering.

The on-site vertex function acts as a local chemical potential.

Calculated interface resistances in layered disordered systems.

Abstract

Coherent potential approximation (CPA) has widely been used for studying residual resistivity of bulk alloys and electrical conductivity in inhomogeneous systems with structural disorder. Here we revisit the single-site CPA within the Landauer-B\"uttiker approach applied to the electronic transport in layered structures and show that this method can be interpreted in terms of the B\"uttiker's voltage-probe model that has been developed for treating phase breaking scattering in mesoscopic systems. We demonstrate that the on-site vertex function which appears within the single-site CPA formalism plays a role of the local chemical potential within the voltage-probe approach. This interpretation allows the determination of the chemical potential profile across a disordered conductor which is useful for analyzing results of transport calculations within the CPA. We illustrate this method by providing several examples. In particular, for layered systems with translational periodicity in the plane of the layers we introduce the local resistivity and calculate the interface resistance between disordered layers.