Molecular-Barrier-Enhanced Aromatic Fluorophores in Cocrystals with Unity Quantum Efficiency

Huanqing Ye; Guangfeng Liu; Sheng Liu; David Casanova; Xin Ye; Xutang Tao; Qichun Zhang; Qihua Xiong

doi:10.1002/anie.201712104

Molecular-Barrier-Enhanced Aromatic Fluorophores in Cocrystals with Unity Quantum Efficiency

Huanqing Ye, Guangfeng Liu, Sheng Liu, David Casanova^*, Xin Ye, Xutang Tao, Qichun Zhang^*, Qihua Xiong^*

^*Corresponding author for this work

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

132 Citations (Scopus)

Abstract

Singlet–triplet conversion in organic light-emitting materials introduces non-emissive (dark) and long-lived triplet states, which represents a significant challenge in constraining the optical properties. There have been considerable attempts at separating singlets and triplets in long-chain polymers, scavenging triplets, and quenching triplets with heavy metals; nonetheless, such triplet-induced loss cannot be fully eliminated. Herein, a new strategy of crafting a periodic molecular barrier into the π-conjugated matrices of organic aromatic fluorophores is reported. The molecular barriers effectively block the singlet-to-triplet pathway, resulting in near-unity photoluminescence quantum efficiency (PLQE) of the organic fluorophores. The transient optical spectroscopy measurements confirm the absence of the triplet absorption. These studies provide a general approach to preventing the formation of dark triplet states in organic semiconductors and bring new opportunities for the development of advanced organic optics and photonics.

Original language	English
Pages (from-to)	1928-1932
Journal	Angewandte Chemie - International Edition
Volume	57
Issue number	7
Online published	6 Jan 2018
DOIs	https://doi.org/10.1002/anie.201712104
Publication status	Published - 12 Feb 2018
Externally published	Yes

Research Keywords

cocrystals
photoluminescence
photophysics
time-resolved spectroscopy

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title = "Molecular-Barrier-Enhanced Aromatic Fluorophores in Cocrystals with Unity Quantum Efficiency",

abstract = "Singlet–triplet conversion in organic light-emitting materials introduces non-emissive (dark) and long-lived triplet states, which represents a significant challenge in constraining the optical properties. There have been considerable attempts at separating singlets and triplets in long-chain polymers, scavenging triplets, and quenching triplets with heavy metals; nonetheless, such triplet-induced loss cannot be fully eliminated. Herein, a new strategy of crafting a periodic molecular barrier into the π-conjugated matrices of organic aromatic fluorophores is reported. The molecular barriers effectively block the singlet-to-triplet pathway, resulting in near-unity photoluminescence quantum efficiency (PLQE) of the organic fluorophores. The transient optical spectroscopy measurements confirm the absence of the triplet absorption. These studies provide a general approach to preventing the formation of dark triplet states in organic semiconductors and bring new opportunities for the development of advanced organic optics and photonics.",

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author = "Huanqing Ye and Guangfeng Liu and Sheng Liu and David Casanova and Xin Ye and Xutang Tao and Qichun Zhang and Qihua Xiong",

year = "2018",

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AU - Ye, Huanqing

AU - Liu, Guangfeng

AU - Liu, Sheng

AU - Casanova, David

AU - Ye, Xin

AU - Tao, Xutang

AU - Zhang, Qichun

AU - Xiong, Qihua

PY - 2018/2/12

Y1 - 2018/2/12

N2 - Singlet–triplet conversion in organic light-emitting materials introduces non-emissive (dark) and long-lived triplet states, which represents a significant challenge in constraining the optical properties. There have been considerable attempts at separating singlets and triplets in long-chain polymers, scavenging triplets, and quenching triplets with heavy metals; nonetheless, such triplet-induced loss cannot be fully eliminated. Herein, a new strategy of crafting a periodic molecular barrier into the π-conjugated matrices of organic aromatic fluorophores is reported. The molecular barriers effectively block the singlet-to-triplet pathway, resulting in near-unity photoluminescence quantum efficiency (PLQE) of the organic fluorophores. The transient optical spectroscopy measurements confirm the absence of the triplet absorption. These studies provide a general approach to preventing the formation of dark triplet states in organic semiconductors and bring new opportunities for the development of advanced organic optics and photonics.

AB - Singlet–triplet conversion in organic light-emitting materials introduces non-emissive (dark) and long-lived triplet states, which represents a significant challenge in constraining the optical properties. There have been considerable attempts at separating singlets and triplets in long-chain polymers, scavenging triplets, and quenching triplets with heavy metals; nonetheless, such triplet-induced loss cannot be fully eliminated. Herein, a new strategy of crafting a periodic molecular barrier into the π-conjugated matrices of organic aromatic fluorophores is reported. The molecular barriers effectively block the singlet-to-triplet pathway, resulting in near-unity photoluminescence quantum efficiency (PLQE) of the organic fluorophores. The transient optical spectroscopy measurements confirm the absence of the triplet absorption. These studies provide a general approach to preventing the formation of dark triplet states in organic semiconductors and bring new opportunities for the development of advanced organic optics and photonics.

KW - cocrystals

KW - photoluminescence

KW - photophysics

KW - time-resolved spectroscopy

KW - cocrystals

KW - photoluminescence

KW - photophysics

KW - time-resolved spectroscopy

KW - cocrystals

KW - photoluminescence

KW - photophysics

KW - time-resolved spectroscopy

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DO - 10.1002/anie.201712104

M3 - RGC 21 - Publication in refereed journal

C2 - 29316076

SN - 1433-7851

VL - 57

SP - 1928

EP - 1932

JO - Angewandte Chemie - International Edition

JF - Angewandte Chemie - International Edition

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ER -

Molecular-Barrier-Enhanced Aromatic Fluorophores in Cocrystals with Unity Quantum Efficiency

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