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Autori principali: Matasovic, Lujo, Murto, Petri, Yu, Shilong, Wang, Wenzhao, Green, James D., Londi, Giacomo, Zeng, Weixuan, Brown, Laura, Myers, William K., Beljonne, David, Olivier, Yoann, Li, Feng, Bronstein, Hugo, Hele, Timothy J. H., Friend, Richard H., Gorgon, Sebastian
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2508.06945
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author Matasovic, Lujo
Murto, Petri
Yu, Shilong
Wang, Wenzhao
Green, James D.
Londi, Giacomo
Zeng, Weixuan
Brown, Laura
Myers, William K.
Beljonne, David
Olivier, Yoann
Li, Feng
Bronstein, Hugo
Hele, Timothy J. H.
Friend, Richard H.
Gorgon, Sebastian
author_facet Matasovic, Lujo
Murto, Petri
Yu, Shilong
Wang, Wenzhao
Green, James D.
Londi, Giacomo
Zeng, Weixuan
Brown, Laura
Myers, William K.
Beljonne, David
Olivier, Yoann
Li, Feng
Bronstein, Hugo
Hele, Timothy J. H.
Friend, Richard H.
Gorgon, Sebastian
contents Excitons in organic materials are emerging as an attractive platform for tunable quantum technologies. Structures with near-degenerate doublet and triplet excitations in linked trityl radical, acene and carbazole units can host quartet states. These high spin states can be coherently manipulated, and later decay radiatively via the radical doublet transition. However, this requires controlling the deexcitation pathways of all metastable states. Here we establish design rules for efficient quartet generation in luminescent radicals, using different connection arrangements of the molecular units. We discover that electronic coupling strength between these units dictates luminescence and quartet formation yields, particularly through the energetics of an acene-radical charge transfer state, which we tune Coulombically. This state acts as a source of non-radiative decay when acene-radical separation is small, but facilitates doublet-quartet spin interconversion when acene-radical separation is large. Using these rules we report a radical-carbazole-acene material with 55% luminescence yield, where 94% of emitting excitons originate from the quartet at microsecond times. This reveals the central role of molecular topology in luminescent quantum materials.
format Preprint
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institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Coulombic control of charge transfer in luminescent radicals with long-lived quartet states
Matasovic, Lujo
Murto, Petri
Yu, Shilong
Wang, Wenzhao
Green, James D.
Londi, Giacomo
Zeng, Weixuan
Brown, Laura
Myers, William K.
Beljonne, David
Olivier, Yoann
Li, Feng
Bronstein, Hugo
Hele, Timothy J. H.
Friend, Richard H.
Gorgon, Sebastian
Materials Science
Mesoscale and Nanoscale Physics
Chemical Physics
Excitons in organic materials are emerging as an attractive platform for tunable quantum technologies. Structures with near-degenerate doublet and triplet excitations in linked trityl radical, acene and carbazole units can host quartet states. These high spin states can be coherently manipulated, and later decay radiatively via the radical doublet transition. However, this requires controlling the deexcitation pathways of all metastable states. Here we establish design rules for efficient quartet generation in luminescent radicals, using different connection arrangements of the molecular units. We discover that electronic coupling strength between these units dictates luminescence and quartet formation yields, particularly through the energetics of an acene-radical charge transfer state, which we tune Coulombically. This state acts as a source of non-radiative decay when acene-radical separation is small, but facilitates doublet-quartet spin interconversion when acene-radical separation is large. Using these rules we report a radical-carbazole-acene material with 55% luminescence yield, where 94% of emitting excitons originate from the quartet at microsecond times. This reveals the central role of molecular topology in luminescent quantum materials.
title Coulombic control of charge transfer in luminescent radicals with long-lived quartet states
topic Materials Science
Mesoscale and Nanoscale Physics
Chemical Physics
url https://arxiv.org/abs/2508.06945