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Індуктивно-резонансний трансфер енергії в гібридних вуглецевих наноструктурах

Based on the first principles, we have shown that the decisive role in energy transfer from the fluorophore molecule to the carbon substrate (graphene) is played by the F?rster-type inductive-resonance energy transfer mechanism. The F?rster energy transfer rate can be calculated analytically via Fer...

Повний опис

Збережено в:
Бібліографічні деталі
Дата:2024
Автори: Semchuk, O. Yu., Havryliuk, O. O., Biliuk, A. A.
Формат: Стаття
Мова:Англійська
Опубліковано: Chuiko Institute of Surface Chemistry National Academy of Sciences of Ukraine 2024
Теми:
графен
вуглецеві нанотрубки
функціоналізований графен
молекула барвника
золоте правило Фермі
швидкість передачі енергії
молекули флуорофора
механізм Фьорстера
механізм Декстера
оптоелектроніка
Онлайн доступ:https://www.cpts.com.ua/index.php/cpts/article/view/732
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Назва журналу:Chemistry, Physics and Technology of Surface

Репозитарії

Chemistry, Physics and Technology of Surface
Опис
Резюме:Based on the first principles, we have shown that the decisive role in energy transfer from the fluorophore molecule to the carbon substrate (graphene) is played by the F?rster-type inductive-resonance energy transfer mechanism. The F?rster energy transfer rate can be calculated analytically via Fermi’s golden rule with the momentum-dependent initial final states of the graphene substrates and the HOMO (the highest occupied molecular orbital) and LUMO (the lowest unoccupied molecular orbital) states of the dye molecule. Combining first-principle calculations characterizing the hybrid carbon nanomaterials with tight-binding-based consideration of graphene wave functions allows us to obtain an analytical expression for the F?rster energy transfer rate. We constructed graphical dependences of the F?rster energy transfer rate at the distance R between substrate (graphene) and dye molecule for several materials. The results obtained can be applied to various hybrids based on carbon nanostructures and in general to the description of energy transfer processes in molecular functionalized nanostructures, once the molecular dipole moment and the substrate - molecule separation are known.

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