Purely organic near-infrared afterglow systems based on a triplet excimer donor

An efficient near-infrared (NIR) afterglow emission at over 750 nm is highly valuable for the advanced detection technology. Herein, a new kind of organic NIR afterglow system with persistent emission (0.16 s) at 808 nm is prepared by using a red room temperature phosphorescence (RTP) excimer as a d...

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Published inJournal of materials chemistry. C, Materials for optical and electronic devices Vol. 12; no. 11; pp. 3924 - 393
Main Authors Lin, Faxu, Chen, Jinzheng, Miao, Yiling, Long, Xiang, Wang, Wen, Hu, Wei, Wang, Haiyang, Huang, Huahua, Liang, Guodong, Chi, Zhenguo
Format Journal Article
LanguageEnglish
Published Cambridge Royal Society of Chemistry 14.03.2024
Subjects
Afterglows
Emission
Energy transfer
Excimers
Near infrared radiation
Phosphorescence
Polyvinyl alcohol
Room temperature
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Abstract An efficient near-infrared (NIR) afterglow emission at over 750 nm is highly valuable for the advanced detection technology. Herein, a new kind of organic NIR afterglow system with persistent emission (0.16 s) at 808 nm is prepared by using a red room temperature phosphorescence (RTP) excimer as a donor and a NIR dye cyanine 7 (Cy7) as an acceptor. In the pyren-1-ylboronic acid@poly(vinyl alcohol) (PYB@PVA) system, its red persistent RTP emission at over 590 nm is proved to be derived from the triplet excimer of PYB. So, the bright NIR afterglow is achieved via only a single triplet-to-singlet Förster-resonance energy transfer process between PYB@PVA and Cy7. Moreover, PYB 2 @PVA with more triplet excimers is beneficial to improve NIR emission intensity with a quantum yield of 1.6%. This work demonstrates that exploiting triplet excimers is meaningful to develop purely organic red or NIR afterglow materials with the emission at a long wavelength. A kind of NIR afterglow with a lifetime of 0.16 s at 808 nm was prepared using triplet excimer (PVB@PVA) as the donor. PYB 2 @PVA containing more excimers is beneficial to improve luminescence of Cy7 acceptor via a triplet-to-singlet energy transfer.
AbstractList An efficient near-infrared (NIR) afterglow emission at over 750 nm is highly valuable for the advanced detection technology. Herein, a new kind of organic NIR afterglow system with persistent emission (0.16 s) at 808 nm is prepared by using a red room temperature phosphorescence (RTP) excimer as a donor and a NIR dye cyanine 7 (Cy7) as an acceptor. In the pyren-1-ylboronic acid@poly(vinyl alcohol) (PYB@PVA) system, its red persistent RTP emission at over 590 nm is proved to be derived from the triplet excimer of PYB. So, the bright NIR afterglow is achieved via only a single triplet-to-singlet Förster-resonance energy transfer process between PYB@PVA and Cy7. Moreover, PYB 2 @PVA with more triplet excimers is beneficial to improve NIR emission intensity with a quantum yield of 1.6%. This work demonstrates that exploiting triplet excimers is meaningful to develop purely organic red or NIR afterglow materials with the emission at a long wavelength. A kind of NIR afterglow with a lifetime of 0.16 s at 808 nm was prepared using triplet excimer (PVB@PVA) as the donor. PYB 2 @PVA containing more excimers is beneficial to improve luminescence of Cy7 acceptor via a triplet-to-singlet energy transfer.
An efficient near-infrared (NIR) afterglow emission at over 750 nm is highly valuable for the advanced detection technology. Herein, a new kind of organic NIR afterglow system with persistent emission (0.16 s) at 808 nm is prepared by using a red room temperature phosphorescence (RTP) excimer as a donor and a NIR dye cyanine 7 (Cy7) as an acceptor. In the pyren-1-ylboronic acid@poly(vinyl alcohol) (PYB@PVA) system, its red persistent RTP emission at over 590 nm is proved to be derived from the triplet excimer of PYB. So, the bright NIR afterglow is achieved via only a single triplet-to-singlet Förster-resonance energy transfer process between PYB@PVA and Cy7. Moreover, PYB 2 @PVA with more triplet excimers is beneficial to improve NIR emission intensity with a quantum yield of 1.6%. This work demonstrates that exploiting triplet excimers is meaningful to develop purely organic red or NIR afterglow materials with the emission at a long wavelength.
An efficient near-infrared (NIR) afterglow emission at over 750 nm is highly valuable for the advanced detection technology. Herein, a new kind of organic NIR afterglow system with persistent emission (0.16 s) at 808 nm is prepared by using a red room temperature phosphorescence (RTP) excimer as a donor and a NIR dye cyanine 7 (Cy7) as an acceptor. In the pyren-1-ylboronic acid@poly(vinyl alcohol) (PYB@PVA) system, its red persistent RTP emission at over 590 nm is proved to be derived from the triplet excimer of PYB. So, the bright NIR afterglow is achieved via only a single triplet-to-singlet Förster-resonance energy transfer process between PYB@PVA and Cy7. Moreover, PYB2@PVA with more triplet excimers is beneficial to improve NIR emission intensity with a quantum yield of 1.6%. This work demonstrates that exploiting triplet excimers is meaningful to develop purely organic red or NIR afterglow materials with the emission at a long wavelength.
Author Chen, Jinzheng
Miao, Yiling
Chi, Zhenguo
Wang, Wen
Hu, Wei
Long, Xiang
Wang, Haiyang
Lin, Faxu
Huang, Huahua
Liang, Guodong
AuthorAffiliation PCFM Lab
School of Materials Science and Engineering
Sun Yat-sen University
School of Chemistry
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Snippet An efficient near-infrared (NIR) afterglow emission at over 750 nm is highly valuable for the advanced detection technology. Herein, a new kind of organic NIR...
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SubjectTerms Afterglows
Emission
Energy transfer
Excimers
Near infrared radiation
Phosphorescence
Polyvinyl alcohol
Room temperature
Title Purely organic near-infrared afterglow systems based on a triplet excimer donor
URI https://www.proquest.com/docview/2956673469
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