Enabling long-lived organic room temperature phosphorescence in polymers by subunit interlocking

Suzhi Cai; Huili Ma; Huifang Shi; He Wang; Xuan Wang; Leixin Xiao; Wenpeng Ye; Kaiwei Huang; Xudong Cao; Nan Gan; Chaoqun Ma; Mingxing Gu; Lulu Song; Hai Xu; Youtian Tao; Chunfeng Zhang; Wei Yao; Zhongfu An; Wei Huang

doi:10.1038/s41467-019-11749-x

Enabling long-lived organic room temperature phosphorescence in polymers by subunit interlocking

Suzhi Cai, Huili Ma, Huifang Shi, He Wang, Xuan Wang, Leixin Xiao, Wenpeng Ye, Kaiwei Huang, Xudong Cao, Nan Gan, Chaoqun Ma, Mingxing Gu, Lulu Song, Hai Xu, Youtian Tao, Chunfeng Zhang, Wei Yao, Zhongfu An, Wei Huang

SCHOOL OF FLEXIBLE ELECTRONICS(FUTURE TECHNOLOGIES)|INSTITUTE OF ADVANCED MATERIALS(IAM)

Research output: Contribution to journal › Article › peer-review

237 Scopus citations

Abstract

Long-lived room temperature phosphorescence (LRTP) is an attractive optical phenomenon in organic electronics and photonics. Despite the rapid advance, it is still a formidable challenge to explore a universal approach to obtain LRTP in amorphous polymers. Based on the traditional polyethylene derivatives, we herein present a facile and concise chemical strategy to achieve ultralong phosphorescence in polymers by ionic bonding cross-linking. Impressively, a record LRTP lifetime of up to 2.1 s in amorphous polymers under ambient conditions is set up. Moreover, multicolor long-lived phosphorescent emission can be procured by tuning the excitation wavelength in single-component polymer materials. These results outline a fundamental principle for the construction of polymer materials with LRTP, endowing traditional polymers with fresh features for potential applications.

Original language	English
Article number	4247
Journal	Nature Communications
Volume	10
Issue number	1
DOIs	https://doi.org/10.1038/s41467-019-11749-x
State	Published - 1 Dec 2019

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title = "Enabling long-lived organic room temperature phosphorescence in polymers by subunit interlocking",

abstract = "Long-lived room temperature phosphorescence (LRTP) is an attractive optical phenomenon in organic electronics and photonics. Despite the rapid advance, it is still a formidable challenge to explore a universal approach to obtain LRTP in amorphous polymers. Based on the traditional polyethylene derivatives, we herein present a facile and concise chemical strategy to achieve ultralong phosphorescence in polymers by ionic bonding cross-linking. Impressively, a record LRTP lifetime of up to 2.1 s in amorphous polymers under ambient conditions is set up. Moreover, multicolor long-lived phosphorescent emission can be procured by tuning the excitation wavelength in single-component polymer materials. These results outline a fundamental principle for the construction of polymer materials with LRTP, endowing traditional polymers with fresh features for potential applications.",

author = "Suzhi Cai and Huili Ma and Huifang Shi and He Wang and Xuan Wang and Leixin Xiao and Wenpeng Ye and Kaiwei Huang and Xudong Cao and Nan Gan and Chaoqun Ma and Mingxing Gu and Lulu Song and Hai Xu and Youtian Tao and Chunfeng Zhang and Wei Yao and Zhongfu An and Wei Huang",

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doi = "10.1038/s41467-019-11749-x",

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T1 - Enabling long-lived organic room temperature phosphorescence in polymers by subunit interlocking

AU - Cai, Suzhi

AU - Ma, Huili

AU - Shi, Huifang

AU - Wang, He

AU - Wang, Xuan

AU - Xiao, Leixin

AU - Ye, Wenpeng

AU - Huang, Kaiwei

AU - Cao, Xudong

AU - Gan, Nan

AU - Ma, Chaoqun

AU - Gu, Mingxing

AU - Song, Lulu

AU - Xu, Hai

AU - Tao, Youtian

AU - Zhang, Chunfeng

AU - Yao, Wei

AU - An, Zhongfu

AU - Huang, Wei

PY - 2019/12/1

Y1 - 2019/12/1

N2 - Long-lived room temperature phosphorescence (LRTP) is an attractive optical phenomenon in organic electronics and photonics. Despite the rapid advance, it is still a formidable challenge to explore a universal approach to obtain LRTP in amorphous polymers. Based on the traditional polyethylene derivatives, we herein present a facile and concise chemical strategy to achieve ultralong phosphorescence in polymers by ionic bonding cross-linking. Impressively, a record LRTP lifetime of up to 2.1 s in amorphous polymers under ambient conditions is set up. Moreover, multicolor long-lived phosphorescent emission can be procured by tuning the excitation wavelength in single-component polymer materials. These results outline a fundamental principle for the construction of polymer materials with LRTP, endowing traditional polymers with fresh features for potential applications.

AB - Long-lived room temperature phosphorescence (LRTP) is an attractive optical phenomenon in organic electronics and photonics. Despite the rapid advance, it is still a formidable challenge to explore a universal approach to obtain LRTP in amorphous polymers. Based on the traditional polyethylene derivatives, we herein present a facile and concise chemical strategy to achieve ultralong phosphorescence in polymers by ionic bonding cross-linking. Impressively, a record LRTP lifetime of up to 2.1 s in amorphous polymers under ambient conditions is set up. Moreover, multicolor long-lived phosphorescent emission can be procured by tuning the excitation wavelength in single-component polymer materials. These results outline a fundamental principle for the construction of polymer materials with LRTP, endowing traditional polymers with fresh features for potential applications.

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DO - 10.1038/s41467-019-11749-x

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SN - 2041-1723

VL - 10

JO - Nature Communications

JF - Nature Communications

IS - 1

M1 - 4247

ER -

Enabling long-lived organic room temperature phosphorescence in polymers by subunit interlocking

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