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Main Authors: Wang, Neng, Chen, Shuyong, Wang, Guo Ping
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2510.27124
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author Wang, Neng
Chen, Shuyong
Wang, Guo Ping
author_facet Wang, Neng
Chen, Shuyong
Wang, Guo Ping
contents We investigate temporal scattering in lossless Drude media and reveal an overlooked role of the zero-frequency flat band associated with static polarization charge. This flat band forms an exceptional line spanning all wavenumbers and can be directly excited during temporal scattering at photonic time interfaces, generating non-propagating static fields alongside the usual reflected and transmitted waves. Eigenvector coalescence at the corresponding exceptional points leads to two distinctive features absent in previously studied systems: a static mode whose amplitude increases linearly with time, and an additional static component arising from the system's generalized eigenvector. Remarkably, these effects occur without violating total energy conservation, underscoring the Hermitian nature of the dynamics. Our findings present a new physical picture of temporal scattering, sharply distinct from that in dispersionless and Lorentz-dispersive media.
format Preprint
id arxiv_https___arxiv_org_abs_2510_27124
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Temporal Scattering at Irremovable Exceptional Points in Lossless Drude Media
Wang, Neng
Chen, Shuyong
Wang, Guo Ping
Optics
We investigate temporal scattering in lossless Drude media and reveal an overlooked role of the zero-frequency flat band associated with static polarization charge. This flat band forms an exceptional line spanning all wavenumbers and can be directly excited during temporal scattering at photonic time interfaces, generating non-propagating static fields alongside the usual reflected and transmitted waves. Eigenvector coalescence at the corresponding exceptional points leads to two distinctive features absent in previously studied systems: a static mode whose amplitude increases linearly with time, and an additional static component arising from the system's generalized eigenvector. Remarkably, these effects occur without violating total energy conservation, underscoring the Hermitian nature of the dynamics. Our findings present a new physical picture of temporal scattering, sharply distinct from that in dispersionless and Lorentz-dispersive media.
title Temporal Scattering at Irremovable Exceptional Points in Lossless Drude Media
topic Optics
url https://arxiv.org/abs/2510.27124