Coherent Virtual Absorption in Dielectric Slabs: A Temporal Analysis of Symmetric and Asymmetric Geometries

TL;DR

This paper investigates coherent virtual absorption in dielectric slabs, analyzing time dynamics in symmetric and asymmetric geometries to enhance energy storage and sensing applications in lossless optical structures.

Contribution

It provides a systematic time domain and spectral filtering analysis of virtual absorption in complex geometries without relying on closed-form solutions.

Findings

Effective time-limited energy storage demonstrated in dielectric slabs.

Analysis methods applicable to multilayered and inhomogeneous structures.

Potential for optimized sensing applications using complex-frequency dynamics.

Abstract

Coherent virtual absorption refers to time-limited storage of optical energy in lossless configurations due to excitation of a complex zero frequency through proper temporal engineering of the incident wave. Given the dynamics underlying the effect and the storage-release mechanism occurring for finite excitation pulses, studying and understanding the associated time dynamics are crucial for enabling future applications. In this work, we carefully investigate this phenomenon in symmetric and asymmetric geometries, shedding light on practical considerations in situations when a closed-form analytical solution is not readily available. Combinations of time domain analysis and spectral filtering are used to enable systematic analysis of these structures. Our approach can be generalized to more complex structures, including multilayered and inhomogeneous cases, providing new opportunities for optimized energy storage and advanced sensing applications utilizing complex-frequency dynamics in lossless designs.