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Autori principali: Grüne, Jeannine, Montanaro, Steph, Bradbury, Thomas W., Sharma, Ashish, Dowland, Simon, Gillett, Alexander J., Gorgon, Sebastian, Millington, Oliver, Myers, William K., Behrends, Jan, Clark, Jenny, Rao, Akshay, Bronstein, Hugo, Greenham, Neil C.
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2410.07891
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author Grüne, Jeannine
Montanaro, Steph
Bradbury, Thomas W.
Sharma, Ashish
Dowland, Simon
Gillett, Alexander J.
Gorgon, Sebastian
Millington, Oliver
Myers, William K.
Behrends, Jan
Clark, Jenny
Rao, Akshay
Bronstein, Hugo
Greenham, Neil C.
author_facet Grüne, Jeannine
Montanaro, Steph
Bradbury, Thomas W.
Sharma, Ashish
Dowland, Simon
Gillett, Alexander J.
Gorgon, Sebastian
Millington, Oliver
Myers, William K.
Behrends, Jan
Clark, Jenny
Rao, Akshay
Bronstein, Hugo
Greenham, Neil C.
contents High-spin states in molecular systems hold significant interest for a wide range of applications ranging from optoelectronics to quantum information and singlet fission (SF). Quintet and triplet states play crucial roles, particularly in SF systems, necessitating a precise monitoring and control of their spin dynamics. Spin states in intramolecular SF (iSF) are of particular interest, but tuning these systems to control triplet multiplication pathways has not been extensively studied. Additionally, whilst studies in this context focus on participation of triplet pathways leading to photoluminescence, emission pathways via quintet states remain largely unexplored. Here, we employ a set of unique spin-sensitive techniques to investigate high-spin state formation and emission in dimers and trimers comprising multiple diphenylhexatriene (DPH) units. We demonstrate the formation of pure quintet states in all these oligomers, with high-spin state optical emission via quintet states dominating delayed fluorescence up to room temperature. For triplet formation, we distinguish between the ability to form weakly exchange-coupled triplet pairs and the efficiency-reducing pathway of intersystem crossing (ISC), identifying the trimer Me-(DPH)$_3$ as the only oligomer exhibiting exclusively the desired SF pathways. Conversely, linear (DPH)$_3$ and (DPH)$_2$ show additional or exclusive triplet pathways via ISC. Our comprehensive analysis provides a detailed investigation into high-spin state formation, control, and emission in intramolecular singlet fission systems.
format Preprint
id arxiv_https___arxiv_org_abs_2410_07891
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle High-Spin State Dynamics and Quintet-Mediated Emission in Intramolecular Singlet Fission
Grüne, Jeannine
Montanaro, Steph
Bradbury, Thomas W.
Sharma, Ashish
Dowland, Simon
Gillett, Alexander J.
Gorgon, Sebastian
Millington, Oliver
Myers, William K.
Behrends, Jan
Clark, Jenny
Rao, Akshay
Bronstein, Hugo
Greenham, Neil C.
Materials Science
Chemical Physics
High-spin states in molecular systems hold significant interest for a wide range of applications ranging from optoelectronics to quantum information and singlet fission (SF). Quintet and triplet states play crucial roles, particularly in SF systems, necessitating a precise monitoring and control of their spin dynamics. Spin states in intramolecular SF (iSF) are of particular interest, but tuning these systems to control triplet multiplication pathways has not been extensively studied. Additionally, whilst studies in this context focus on participation of triplet pathways leading to photoluminescence, emission pathways via quintet states remain largely unexplored. Here, we employ a set of unique spin-sensitive techniques to investigate high-spin state formation and emission in dimers and trimers comprising multiple diphenylhexatriene (DPH) units. We demonstrate the formation of pure quintet states in all these oligomers, with high-spin state optical emission via quintet states dominating delayed fluorescence up to room temperature. For triplet formation, we distinguish between the ability to form weakly exchange-coupled triplet pairs and the efficiency-reducing pathway of intersystem crossing (ISC), identifying the trimer Me-(DPH)$_3$ as the only oligomer exhibiting exclusively the desired SF pathways. Conversely, linear (DPH)$_3$ and (DPH)$_2$ show additional or exclusive triplet pathways via ISC. Our comprehensive analysis provides a detailed investigation into high-spin state formation, control, and emission in intramolecular singlet fission systems.
title High-Spin State Dynamics and Quintet-Mediated Emission in Intramolecular Singlet Fission
topic Materials Science
Chemical Physics
url https://arxiv.org/abs/2410.07891