Fluorescence via Reverse Intersystem Crossing from Higher Triplet States in a Bisanthracene Derivative

Fluorescence via Reverse Intersystem Crossing from Higher Triplet States in a Bisanthracene Derivative

Abstract To elucidate the high external quantum efficiency observed for organic light-emitting diodes using a bisanthracene derivative (BD1), non-radiative transition processes as well as radiative ones are discussed employing time-dependent density functional theory. It has been previously reported...

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Main Authors: Tohru Sato, Rika Hayashi, Naoki Haruta, Yong-Jin Pu
Format: Article
Language:English
Published: Nature Publishing Group 2017-07-01
Series:Scientific Reports
Online Access:https://doi.org/10.1038/s41598-017-05007-7
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spelling doaj-978653d273474d1bbf622d2acbdca4882020-12-08T03:08:00ZengNature Publishing GroupScientific Reports2045-23222017-07-01711910.1038/s41598-017-05007-7Fluorescence via Reverse Intersystem Crossing from Higher Triplet States in a Bisanthracene DerivativeTohru Sato0Rika Hayashi1Naoki Haruta2Yong-Jin Pu3Department of Molecular Engineering, Graduate School of Engineering, Kyoto UniversityUndergraduate School of Industrial Chemistry, Faculty of Engineering, Kyoto UniversityDepartment of Molecular Engineering, Graduate School of Engineering, Kyoto UniversityGraduate School of Organic Materials Science, Yamagata UniversityAbstract To elucidate the high external quantum efficiency observed for organic light-emitting diodes using a bisanthracene derivative (BD1), non-radiative transition processes as well as radiative ones are discussed employing time-dependent density functional theory. It has been previously reported that the observed high external quantum efficiency of BD1 cannot be explained by the conventional thermally activated delayed fluorescence involving T1 exciton nor triplet-triplet annihilation. The calculated off-diagonal vibronic coupling constants of BD1, which govern the non-radiative transition rates, suggest a fluorescence via higher triplets (FvHT) mechanism, which entails the conversion of a high triplet exciton generated during electrical excitation into a fluorescent singlet exciton. This mechanism is valid as long as the relaxation of high triplet states to lower states is suppressed. In the case of BD1, its pseudo-degenerate electronic structure helps the suppression. A general condition is also discussed for the suppression of transitions in molecules with pseudo-degenerate electronic structures.https://doi.org/10.1038/s41598-017-05007-7
collection DOAJ
language English
format Article
sources DOAJ
author Tohru Sato
Rika Hayashi
Naoki Haruta
Yong-Jin Pu
spellingShingle Tohru Sato
Rika Hayashi
Naoki Haruta
Yong-Jin Pu
Fluorescence via Reverse Intersystem Crossing from Higher Triplet States in a Bisanthracene Derivative
Scientific Reports
author_facet Tohru Sato
Rika Hayashi
Naoki Haruta
Yong-Jin Pu
author_sort Tohru Sato
title Fluorescence via Reverse Intersystem Crossing from Higher Triplet States in a Bisanthracene Derivative
title_short Fluorescence via Reverse Intersystem Crossing from Higher Triplet States in a Bisanthracene Derivative
title_full Fluorescence via Reverse Intersystem Crossing from Higher Triplet States in a Bisanthracene Derivative
title_fullStr Fluorescence via Reverse Intersystem Crossing from Higher Triplet States in a Bisanthracene Derivative
title_full_unstemmed Fluorescence via Reverse Intersystem Crossing from Higher Triplet States in a Bisanthracene Derivative
title_sort fluorescence via reverse intersystem crossing from higher triplet states in a bisanthracene derivative
publisher Nature Publishing Group
series Scientific Reports
issn 2045-2322
publishDate 2017-07-01
description Abstract To elucidate the high external quantum efficiency observed for organic light-emitting diodes using a bisanthracene derivative (BD1), non-radiative transition processes as well as radiative ones are discussed employing time-dependent density functional theory. It has been previously reported that the observed high external quantum efficiency of BD1 cannot be explained by the conventional thermally activated delayed fluorescence involving T1 exciton nor triplet-triplet annihilation. The calculated off-diagonal vibronic coupling constants of BD1, which govern the non-radiative transition rates, suggest a fluorescence via higher triplets (FvHT) mechanism, which entails the conversion of a high triplet exciton generated during electrical excitation into a fluorescent singlet exciton. This mechanism is valid as long as the relaxation of high triplet states to lower states is suppressed. In the case of BD1, its pseudo-degenerate electronic structure helps the suppression. A general condition is also discussed for the suppression of transitions in molecules with pseudo-degenerate electronic structures.
url https://doi.org/10.1038/s41598-017-05007-7
work_keys_str_mv AT tohrusato fluorescenceviareverseintersystemcrossingfromhighertripletstatesinabisanthracenederivative
AT rikahayashi fluorescenceviareverseintersystemcrossingfromhighertripletstatesinabisanthracenederivative
AT naokiharuta fluorescenceviareverseintersystemcrossingfromhighertripletstatesinabisanthracenederivative
AT yongjinpu fluorescenceviareverseintersystemcrossingfromhighertripletstatesinabisanthracenederivative
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