Twofold rigidity activates ultralong organic high-temperature phosphorescence

Kaijun Chen; Yongfeng Zhang; Yunxiang Lei; Wenbo Dai; Miaochang Liu; Zhengxu Cai; Huayue Wu; Xiaobo Huang; Xiang Ma

doi:10.1038/s41467-024-45678-1

Twofold rigidity activates ultralong organic high-temperature phosphorescence

Kaijun Chen
, Yongfeng Zhang
, Yunxiang Lei^*
, Wenbo Dai
, Miaochang Liu
, Zhengxu Cai
, Huayue Wu
, Xiaobo Huang^*
, Xiang Ma^*

^*Corresponding author for this work

School of Material Science and Engineering

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

116 Citations (Scopus)

Abstract

A strategy is pioneered for achieving high-temperature phosphorescence using planar rigid molecules as guests and rigid polymers as host matrix. The planar rigid configuration can resist the thermal vibration of the guest at high temperatures, and the rigidity of the matrix further enhances the high-temperature resistance of the guest. The doped materials exhibit an afterglow of 40 s at 293 K, 20 s at 373 K, 6 s at 413 K, and a 1 s afterglow at 433 K. The experimental results indicate that as the rotational ability of the groups connected to the guests gradually increases, the high-temperature phosphorescence performance of the doped materials gradually decreases. In addition, utilizing the property of doped materials that can emit phosphorescence at high temperatures and in high smoke, the attempt is made to use organic phosphorescence materials to identify rescue workers and trapped personnel in fires.

Original language	English
Article number	1269
Journal	Nature Communications
Volume	15
Issue number	1
DOIs	https://doi.org/10.1038/s41467-024-45678-1
Publication status	Published - Dec 2024

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title = "Twofold rigidity activates ultralong organic high-temperature phosphorescence",

abstract = "A strategy is pioneered for achieving high-temperature phosphorescence using planar rigid molecules as guests and rigid polymers as host matrix. The planar rigid configuration can resist the thermal vibration of the guest at high temperatures, and the rigidity of the matrix further enhances the high-temperature resistance of the guest. The doped materials exhibit an afterglow of 40 s at 293 K, 20 s at 373 K, 6 s at 413 K, and a 1 s afterglow at 433 K. The experimental results indicate that as the rotational ability of the groups connected to the guests gradually increases, the high-temperature phosphorescence performance of the doped materials gradually decreases. In addition, utilizing the property of doped materials that can emit phosphorescence at high temperatures and in high smoke, the attempt is made to use organic phosphorescence materials to identify rescue workers and trapped personnel in fires.",

author = "Kaijun Chen and Yongfeng Zhang and Yunxiang Lei and Wenbo Dai and Miaochang Liu and Zhengxu Cai and Huayue Wu and Xiaobo Huang and Xiang Ma",

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doi = "10.1038/s41467-024-45678-1",

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T1 - Twofold rigidity activates ultralong organic high-temperature phosphorescence

AU - Chen, Kaijun

AU - Zhang, Yongfeng

AU - Lei, Yunxiang

AU - Dai, Wenbo

AU - Liu, Miaochang

AU - Cai, Zhengxu

AU - Wu, Huayue

AU - Huang, Xiaobo

AU - Ma, Xiang

PY - 2024/12

Y1 - 2024/12

N2 - A strategy is pioneered for achieving high-temperature phosphorescence using planar rigid molecules as guests and rigid polymers as host matrix. The planar rigid configuration can resist the thermal vibration of the guest at high temperatures, and the rigidity of the matrix further enhances the high-temperature resistance of the guest. The doped materials exhibit an afterglow of 40 s at 293 K, 20 s at 373 K, 6 s at 413 K, and a 1 s afterglow at 433 K. The experimental results indicate that as the rotational ability of the groups connected to the guests gradually increases, the high-temperature phosphorescence performance of the doped materials gradually decreases. In addition, utilizing the property of doped materials that can emit phosphorescence at high temperatures and in high smoke, the attempt is made to use organic phosphorescence materials to identify rescue workers and trapped personnel in fires.

AB - A strategy is pioneered for achieving high-temperature phosphorescence using planar rigid molecules as guests and rigid polymers as host matrix. The planar rigid configuration can resist the thermal vibration of the guest at high temperatures, and the rigidity of the matrix further enhances the high-temperature resistance of the guest. The doped materials exhibit an afterglow of 40 s at 293 K, 20 s at 373 K, 6 s at 413 K, and a 1 s afterglow at 433 K. The experimental results indicate that as the rotational ability of the groups connected to the guests gradually increases, the high-temperature phosphorescence performance of the doped materials gradually decreases. In addition, utilizing the property of doped materials that can emit phosphorescence at high temperatures and in high smoke, the attempt is made to use organic phosphorescence materials to identify rescue workers and trapped personnel in fires.

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VL - 15

JO - Nature Communications

JF - Nature Communications

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ER -

Twofold rigidity activates ultralong organic high-temperature phosphorescence

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