Enhanced Room‐Temperature Phosphorescence through Intermolecular Halogen/Hydrogen Bonding

Room‐temperature phosphorescence (RTP) materials with high efficiency have attracted much attention because they have unique characteristics that cannot be realized in conventional fluorescent materials. Unfortunately, efficient RTP in metal‐free organic materials is very rare and it has traditional...

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Published in:Chemistry : a European journal 2019-01, Vol.25 (3), p.714-723
Main Authors: Xiao, Lu, Fu, Hongbing
Format: Article
Language:English
Subjects:
Chemistry
Fluorescence
halogen bonds
Hydrogen bonding
hydrogen bonds
Inorganic compounds
luminescence
Metals
noncovalent interactions
Organic chemistry
Organic compounds
Organic materials
Phosphorescence
Room temperature
room-temperature phosphorescence
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description Room‐temperature phosphorescence (RTP) materials with high efficiency have attracted much attention because they have unique characteristics that cannot be realized in conventional fluorescent materials. Unfortunately, efficient RTP in metal‐free organic materials is very rare and it has traditionally been considered as the feature to divide purely organic compounds from organometallic and inorganic compounds. There has been increasing research interest in the design and preparation of metal‐free organic RTP materials in recent years. It has been reported that intermolecular interactions make a big difference to the photophysical behavior of organic molecules. In this regard, herein, the parameters that affect RTP efficiency are discussed, and a brief review of recent intermolecular halogen‐/hydrogen‐bonding strategies for efficient RTP in metal‐free organic materials are provided. The opportunities and challenges are finally elaborated in the hope of guiding promising directions for the design and application of RTP materials. Fixed formations: Room‐temperature phosphorescence (RTP) materials have attracted increasing research interest because of their promising functional applications. Recent examples of intermolecular halogen‐/hydrogen‐bonding strategies for efficient RTP in metal‐free organic materials are summarized.
doi_str_mv 10.1002/chem.201802819
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1521-3765
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subjects Chemistry
Fluorescence
halogen bonds
Hydrogen bonding
hydrogen bonds
Inorganic compounds
luminescence
Metals
noncovalent interactions
Organic chemistry
Organic compounds
Organic materials
Phosphorescence
Room temperature
room-temperature phosphorescence
title Enhanced Room‐Temperature Phosphorescence through Intermolecular Halogen/Hydrogen Bonding
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