General model of nonradiative excitation energy migration on a spherical nanoparticle with attached chromophores

Kułak, L.; Schlichtholz, A.; Bojarski, P.

doi:10.1038/s41598-024-55193-4

Sci Rep

2024

DOI: 10.1038/s41598-024-55193-4

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General model of nonradiative excitation energy migration on a spherical nanoparticle with attached chromophores

L. Kułak,

A. Schlichtholz,

P. Bojarski

Abstract: Theory of multistep excitation energy migration within the set of chemically identical chromophores distributed on the surface of a spherical nanoparticle is presented. The Green function solution to the master equation is expanded as a diagrammatic series. Topological reduction of the series leads to the expression for emission anisotropy decay. The solution obtained behaves very well over the whole time range and it remains accurate even for a high number of the attached chromophores. Emission anisotropy dec… Show more

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Cited by 2 publications

References 29 publications

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Nanocomposites with cylindrical/rectangular/spherical/ellipsoidal reinforcements: Generalized continuum mechanics

Janghorban

2024

International Journal of Engineering Science

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Nanocomposites with cylindrical/rectangular/spherical/ellipsoidal reinforcements: Generalized continuum mechanics

Janghorban

2024

International Journal of Engineering Science

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Theoretical model of donor–donor and donor–acceptor energy transfer on a nanosphere

Synak,

Kułak,

Bojarski

2024

Sci Rep

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In this study, we introduce a novel advancement in the field of theoretical exploration. Specifically, we investigate the transfer and trapping of electronic excitations within a two-component disordered system confined to a finite volume. The implications of our research extend to energy transfer phenomena on spherical nanoparticles, characterized by randomly distributed donors and acceptors on their surface. Utilizing the three-body Padé approximant technique, previously employed in single-component systems, we apply it to address the challenge of trapping within our system. To validate the robustness of our model, we conduct Monte Carlo simulations on a donor–acceptor system positioned on a spherical nanoparticle. In particular, very good agreement between the model and Monte Carlo simulations has been found for donor fluorescence intensity decay.

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General model of nonradiative excitation energy migration on a spherical nanoparticle with attached chromophores

Cited by 2 publications

References 29 publications

Nanocomposites with cylindrical/rectangular/spherical/ellipsoidal reinforcements: Generalized continuum mechanics

Nanocomposites with cylindrical/rectangular/spherical/ellipsoidal reinforcements: Generalized continuum mechanics

Theoretical model of donor–donor and donor–acceptor energy transfer on a nanosphere

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