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Hauptverfasser: Petrosyan, L. S., Noginov, M. N., Shahbazyan, T. V.
Format: Preprint
Veröffentlicht: 2025
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Online-Zugang:https://arxiv.org/abs/2504.13456
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author Petrosyan, L. S.
Noginov, M. N.
Shahbazyan, T. V.
author_facet Petrosyan, L. S.
Noginov, M. N.
Shahbazyan, T. V.
contents We present an analytical model for Forster resonance energy transfer (FRET) between a donor and an acceptor placed in inhomogeneous and absorptive environment characterized by complex dielectric function, e.g., near a metal-dielectric structure. By extending the standard approach to FRET to include energy transfer (ET) channel to the environment, we show that, in the absence of plasmonic enhancement effects, the Forster radius, which defines the characteristic distance for efficient FRET, is reduced due to a competing ET process. We demonstrate that a reduction of the Forster radius can affect dramatically fluorescence from large ensemble of molecules whose emission kinetics is dominated by FRET-induced concentration quenching. Specifically, we perform numerical calculations for dye-doped polymer films deposited on top of metallic substrate to find that, for high dye concentrations, the emission kinetics slows down considerably, in sharp contrast to acceleration of single-molecule fluorescence. Furthermore, the calculated effective fluorescence decay rate exhibits non-monotonic behavior with varying film thickness, consistent with the experiment, indicating a non-trivial interplay between the metal quenching and concentration quenching mechanisms.
format Preprint
id arxiv_https___arxiv_org_abs_2504_13456
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Forster resonance energy transfer in inhomogeneous and absorptive environment
Petrosyan, L. S.
Noginov, M. N.
Shahbazyan, T. V.
Mesoscale and Nanoscale Physics
We present an analytical model for Forster resonance energy transfer (FRET) between a donor and an acceptor placed in inhomogeneous and absorptive environment characterized by complex dielectric function, e.g., near a metal-dielectric structure. By extending the standard approach to FRET to include energy transfer (ET) channel to the environment, we show that, in the absence of plasmonic enhancement effects, the Forster radius, which defines the characteristic distance for efficient FRET, is reduced due to a competing ET process. We demonstrate that a reduction of the Forster radius can affect dramatically fluorescence from large ensemble of molecules whose emission kinetics is dominated by FRET-induced concentration quenching. Specifically, we perform numerical calculations for dye-doped polymer films deposited on top of metallic substrate to find that, for high dye concentrations, the emission kinetics slows down considerably, in sharp contrast to acceleration of single-molecule fluorescence. Furthermore, the calculated effective fluorescence decay rate exhibits non-monotonic behavior with varying film thickness, consistent with the experiment, indicating a non-trivial interplay between the metal quenching and concentration quenching mechanisms.
title Forster resonance energy transfer in inhomogeneous and absorptive environment
topic Mesoscale and Nanoscale Physics
url https://arxiv.org/abs/2504.13456