Causality and Passivity: from Electromagnetism and Network Theory to Metamaterials

TL;DR

This review explores how principles of causality and passivity underpin various physical theories and their application to metamaterials, highlighting their historical development, mathematical foundations, and impact on material design.

Contribution

It provides a unified framework connecting causality and passivity with dispersion relations and demonstrates their influence on the development and limitations of metamaterials.

Findings

Causality implies passivity in physical systems.

Dispersion relations are extended to tensorial and distributional transfer functions.

Passivity imposes fundamental limits on metamaterial properties and performance.

Abstract

In this review, we take an extensive look at the role that the principles of causality and passivity have played in various areas of physics and engineering, including in the modern field of metamaterials. The aim is not to provide a comprehensive list of references as that number would be in the thousands, but to review the major results and contributions which have animated these areas and to provide a unified framework from which to understand the developments in different fields. Towards these goals, we chart the early history of the field through its dual beginnings in the analysis of the Sellmeier equation and in Hilbert transforms, giving rise to the far reaching dispersion relations in the early works of Kramers, Kronig, and Titchmarsh. However, these early relations constitute a limited result as they only apply to a restricted class of transfer functions. To understand how this restriction can be lifted, we take a quick detour into the distributional analysis of Schwartz. This approach expands the reach of the dispersion analysis to distributional transfer functions and also to those functions which exhibit polynomial growth properties. To generalize the results even further to tensorial transfer functions, we consider the concept of passivity - originally studied in the theory of electrical networks. We clarify why passivity implies causality. Subsequently, as special cases, we present examples of dispersion relations from several areas of physics including electromagnetism, acoustics, seismology, reflectance measurements, and scattering theory. We discuss sum rules, derivative analyticity relations, and nearly local approximations. Finally we review the clever applications of ideas from causality and passivity to the recent field of metamaterials. These ideas have provided limits to what can be achieved in metamaterial property design and metamaterial device performance.