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Main Authors: Korovina, Nadezhda V., OSullivan, Shea, Kelm, Jennica, Lin, Yunhui L., Lloyd, Katherine, Johnson, Justin C.
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2409.17393
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author Korovina, Nadezhda V.
OSullivan, Shea
Kelm, Jennica
Lin, Yunhui L.
Lloyd, Katherine
Johnson, Justin C.
author_facet Korovina, Nadezhda V.
OSullivan, Shea
Kelm, Jennica
Lin, Yunhui L.
Lloyd, Katherine
Johnson, Justin C.
contents Endothermic singlet fission (SF), an exciton multiplication process that produces a pair of high-energy triplet excitons (T1T1), is appealing for photovoltaic or photoelectrochemical applications, as it allows the conversion of entropy into electronic or chemical energy. The mechanistic aspects of this process are not entirely known, and strategies for improving the yield of triplets via endothermic SF have not been developed. In this work we provide experimental evidence that in photoexcited dimers of perylene, S1 is initially in equilibrium with 1(T1T1), and that the lifetime of this equilibrium can be controlled through strategic changes in the radiative rate. Through careful molecular design we fine-tune both the degree of endothermicity and excited state lifetimes in four perylene dimers. Using transient absorption and time resolved fluorescence, we reveal that the dimer with the slowest radiative rate constant produces the most prolonged 1(T1T1). However, in the dimers, the annihilation of the 1(T1T1) state results in a single long-lived triplet rather than a pair, and increasing the free triplet yield above 100% would require additional chromophores.
format Preprint
id arxiv_https___arxiv_org_abs_2409_17393
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Modulating Endothermic Singlet Fission by Controlling Radiative Rates in Perylene Dimers
Korovina, Nadezhda V.
OSullivan, Shea
Kelm, Jennica
Lin, Yunhui L.
Lloyd, Katherine
Johnson, Justin C.
Chemical Physics
Endothermic singlet fission (SF), an exciton multiplication process that produces a pair of high-energy triplet excitons (T1T1), is appealing for photovoltaic or photoelectrochemical applications, as it allows the conversion of entropy into electronic or chemical energy. The mechanistic aspects of this process are not entirely known, and strategies for improving the yield of triplets via endothermic SF have not been developed. In this work we provide experimental evidence that in photoexcited dimers of perylene, S1 is initially in equilibrium with 1(T1T1), and that the lifetime of this equilibrium can be controlled through strategic changes in the radiative rate. Through careful molecular design we fine-tune both the degree of endothermicity and excited state lifetimes in four perylene dimers. Using transient absorption and time resolved fluorescence, we reveal that the dimer with the slowest radiative rate constant produces the most prolonged 1(T1T1). However, in the dimers, the annihilation of the 1(T1T1) state results in a single long-lived triplet rather than a pair, and increasing the free triplet yield above 100% would require additional chromophores.
title Modulating Endothermic Singlet Fission by Controlling Radiative Rates in Perylene Dimers
topic Chemical Physics
url https://arxiv.org/abs/2409.17393