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Main Authors: Galiffi, Emanuele, Harwood, Anthony C., Vezzoli, Stefano, Tirole, Romain, Alù, Andrea, Sapienza, Riccardo
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2410.16426
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author Galiffi, Emanuele
Harwood, Anthony C.
Vezzoli, Stefano
Tirole, Romain
Alù, Andrea
Sapienza, Riccardo
author_facet Galiffi, Emanuele
Harwood, Anthony C.
Vezzoli, Stefano
Tirole, Romain
Alù, Andrea
Sapienza, Riccardo
contents Time-invariant photonic structures amplify or absorb light based on their intrinsic material gain or loss. The coherent interference of multiple beams in space, e.g., in a resonator, can be exploited to tailor the wave interaction with material gain or loss, respectively maximizing lasing or coherent perfect absorption. By contrast, a time-varying system is not bound to conserve energy, even in the absence of material gain or loss, and can support amplification or absorption of a probe wave through parametric phenomena. Here, we demonstrate theoretically and experimentally how a subwavelength film of indium tin oxide, whose bulk permittivity is homogeneously and periodically modulated via optical pumping, can be dynamically tuned to act both as a non-resonant amplifier and a perfect absorber, by manipulating the relative phase of two counterpropagating probe beams. This extends the concept of coherent perfect absorption to the temporal domain. We interpret this result as selective switching between the gain and loss modes present in the momentum bandgap of a periodically modulated medium. By tailoring the relative intensity of the two probes, high-contrast modulation can be achieved with up to 80% absorption and 400% amplification. Our results demonstrate control of gain and loss in time-varying media at optical frequencies and pave the way towards coherent manipulation of light in Floquet-engineered complex photonic systems.
format Preprint
id arxiv_https___arxiv_org_abs_2410_16426
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Optical coherent perfect absorption and amplification in a time-varying medium
Galiffi, Emanuele
Harwood, Anthony C.
Vezzoli, Stefano
Tirole, Romain
Alù, Andrea
Sapienza, Riccardo
Optics
Applied Physics
Time-invariant photonic structures amplify or absorb light based on their intrinsic material gain or loss. The coherent interference of multiple beams in space, e.g., in a resonator, can be exploited to tailor the wave interaction with material gain or loss, respectively maximizing lasing or coherent perfect absorption. By contrast, a time-varying system is not bound to conserve energy, even in the absence of material gain or loss, and can support amplification or absorption of a probe wave through parametric phenomena. Here, we demonstrate theoretically and experimentally how a subwavelength film of indium tin oxide, whose bulk permittivity is homogeneously and periodically modulated via optical pumping, can be dynamically tuned to act both as a non-resonant amplifier and a perfect absorber, by manipulating the relative phase of two counterpropagating probe beams. This extends the concept of coherent perfect absorption to the temporal domain. We interpret this result as selective switching between the gain and loss modes present in the momentum bandgap of a periodically modulated medium. By tailoring the relative intensity of the two probes, high-contrast modulation can be achieved with up to 80% absorption and 400% amplification. Our results demonstrate control of gain and loss in time-varying media at optical frequencies and pave the way towards coherent manipulation of light in Floquet-engineered complex photonic systems.
title Optical coherent perfect absorption and amplification in a time-varying medium
topic Optics
Applied Physics
url https://arxiv.org/abs/2410.16426