Unveiling One‐to‐One Correspondence Between Excited Triplet States and Determinate Interactions by Temperature‐Controllable Blue‐Green‐Yellow Afterglow

Phosphorescence of organic materials is highly dependent on intermolecular interactions, for the sensitive triplet excitons toward environment and aggregated structures. However, until now, relationship between phosphorescence and intermolecular interactions is still unclear for complicated influenc...

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Published inAngewandte Chemie International Edition Vol. 62; no. 24; pp. e202302792 - n/a
Main Authors Liu, Xiuxing, Liao, Qiuyan, Yang, Jie, Li, Zhen, Li, Qianqian
Format Journal Article
LanguageEnglish
Published WEINHEIM Wiley 12.06.2023
Wiley Subscription Services, Inc
EditionInternational ed. in English
Subjects
Afterglows
Chemistry
Chemistry, Multidisciplinary
Controllability
Deuteration
Excitons
Hierarchical Control
Intermolecular Interaction
Organic Luminogen
Organic materials
Phosphorescence
Physical Sciences
Science & Technology
Temperature Modulation
MOLECULAR PACKING
POLYMERS
PERSISTENT
DESIGN
LUMINOGENS
Intermolecular Interaction
Temperature Modulation
Phosphorescence
Organic Luminogen
Hierarchical Control
Online AccessGet full text
ISSN1433-7851
1521-3773
1521-3773
DOI10.1002/anie.202302792

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Abstract Phosphorescence of organic materials is highly dependent on intermolecular interactions, for the sensitive triplet excitons toward environment and aggregated structures. However, until now, relationship between phosphorescence and intermolecular interactions is still unclear for complicated influence factors and uncontrollable aggregated behaviors. Herein, taking temperature as the controlled variable, the afterglow can continuously change from blue to green, then to yellow, even achieve the white emission with deuteration process. It is mainly due to the hierarchical architectures of molecular aggregates with rational distribution of intermolecular interactions, as well as gradually unlocking process of interactions with different energies. Accordingly, the one‐to‐one correspondence between the determinate interactions and excited triplet states have been established, guiding accurate design of desirable phosphorescence materials by hierarchical control of aggregated structures. The one‐to‐one correspondence between excited triplet states and the determinate intermolecular interactions has been established for the first time, by temperature‐controllable blue‐green‐yellow afterglow with hierarchically unlocking intermolecular interactions, which was further confirmed and improved by the deuterated analogue, guiding the accurate design of desirable phosphorescence materials by hierarchical control of aggregated structures.
AbstractList Phosphorescence of organic materials is highly dependent on intermolecular interactions, for the sensitive triplet excitons toward environment and aggregated structures. However, until now, relationship between phosphorescence and intermolecular interactions is still unclear for complicated influence factors and uncontrollable aggregated behaviors. Herein, taking temperature as the controlled variable, the afterglow can continuously change from blue to green, then to yellow, even achieve the white emission with deuteration process. It is mainly due to the hierarchical architectures of molecular aggregates with rational distribution of intermolecular interactions, as well as gradually unlocking process of interactions with different energies. Accordingly, the one-to-one correspondence between the determinate interactions and excited triplet states have been established, guiding accurate design of desirable phosphorescence materials by hierarchical control of aggregated structures.Phosphorescence of organic materials is highly dependent on intermolecular interactions, for the sensitive triplet excitons toward environment and aggregated structures. However, until now, relationship between phosphorescence and intermolecular interactions is still unclear for complicated influence factors and uncontrollable aggregated behaviors. Herein, taking temperature as the controlled variable, the afterglow can continuously change from blue to green, then to yellow, even achieve the white emission with deuteration process. It is mainly due to the hierarchical architectures of molecular aggregates with rational distribution of intermolecular interactions, as well as gradually unlocking process of interactions with different energies. Accordingly, the one-to-one correspondence between the determinate interactions and excited triplet states have been established, guiding accurate design of desirable phosphorescence materials by hierarchical control of aggregated structures.
Phosphorescence of organic materials is highly dependent on intermolecular interactions, for the sensitive triplet excitons toward environment and aggregated structures. However, until now, relationship between phosphorescence and intermolecular interactions is still unclear for complicated influence factors and uncontrollable aggregated behaviors. Herein, taking temperature as the controlled variable, the afterglow can continuously change from blue to green, then to yellow, even achieve the white emission with deuteration process. It is mainly due to the hierarchical architectures of molecular aggregates with rational distribution of intermolecular interactions, as well as gradually unlocking process of interactions with different energies. Accordingly, the one‐to‐one correspondence between the determinate interactions and excited triplet states have been established, guiding accurate design of desirable phosphorescence materials by hierarchical control of aggregated structures.
Phosphorescence of organic materials is highly dependent on intermolecular interactions, for the sensitive triplet excitons toward environment and aggregated structures. However, until now, relationship between phosphorescence and intermolecular interactions is still unclear for complicated influence factors and uncontrollable aggregated behaviors. Herein, taking temperature as the controlled variable, the afterglow can continuously change from blue to green, then to yellow, even achieve the white emission with deuteration process. It is mainly due to the hierarchical architectures of molecular aggregates with rational distribution of intermolecular interactions, as well as gradually unlocking process of interactions with different energies. Accordingly, the one‐to‐one correspondence between the determinate interactions and excited triplet states have been established, guiding accurate design of desirable phosphorescence materials by hierarchical control of aggregated structures. The one‐to‐one correspondence between excited triplet states and the determinate intermolecular interactions has been established for the first time, by temperature‐controllable blue‐green‐yellow afterglow with hierarchically unlocking intermolecular interactions, which was further confirmed and improved by the deuterated analogue, guiding the accurate design of desirable phosphorescence materials by hierarchical control of aggregated structures.
Author Yang, Jie
Li, Zhen
Liao, Qiuyan
Li, Qianqian
Liu, Xiuxing
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Issue 24
Keywords MOLECULAR PACKING
POLYMERS
PERSISTENT
DESIGN
LUMINOGENS
Intermolecular Interaction
Temperature Modulation
Phosphorescence
Organic Luminogen
Hierarchical Control
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Snippet Phosphorescence of organic materials is highly dependent on intermolecular interactions, for the sensitive triplet excitons toward environment and aggregated...
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StartPage e202302792
SubjectTerms Afterglows
Chemistry
Chemistry, Multidisciplinary
Controllability
Deuteration
Excitons
Hierarchical Control
Intermolecular Interaction
Organic Luminogen
Organic materials
Phosphorescence
Physical Sciences
Science & Technology
Temperature Modulation
Title Unveiling One‐to‐One Correspondence Between Excited Triplet States and Determinate Interactions by Temperature‐Controllable Blue‐Green‐Yellow Afterglow
URI https://onlinelibrary.wiley.com/doi/abs/10.1002%2Fanie.202302792
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https://www.ncbi.nlm.nih.gov/pubmed/37073723
https://www.proquest.com/docview/2821521741
https://www.proquest.com/docview/2803328502
Volume 62
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