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Ultralong room temperature phosphorescence from amorphous organic materials toward confidential information encryption and decryption.


ABSTRACT: Ultralong room temperature phosphorescence (URTP) emitted from pure amorphous organic molecules is very rare. Although a few crystalline organic molecules could realize URTP with long lifetimes (>100 ms), practical applications of these crystalline organic phosphors are still challenging because the formation and maintenance of high-quality crystals are very difficult and complicated. Herein, we present a rational design for minimizing the vibrational dissipation of pure amorphous organic molecules to achieve URTP. By using this strategy, a series of URTP films with long lifetimes and high phosphorescent quantum yields (up to 0.75 s and 11.23%, respectively) were obtained from amorphous organic phosphors without visible fluorescence and phosphorescence under ambient conditions. On the basis of the unique features of URTP films, a new green screen printing technology without using any ink was developed toward confidential information encryption and decryption. This work presents a breakthrough strategy in applying amorphous organic materials for URTP.

SUBMITTER: Su Y 

PROVIDER: S-EPMC5935477 | biostudies-literature | 2018 May

REPOSITORIES: biostudies-literature

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Ultralong room temperature phosphorescence from amorphous organic materials toward confidential information encryption and decryption.

Su Yan Y   Phua Soo Zeng Fiona SZF   Li Youbing Y   Zhou Xianju X   Jana Deblin D   Liu Guofeng G   Lim Wei Qi WQ   Ong Wee Kong WK   Yang Chaolong C   Zhao Yanli Y  

Science advances 20180504 5


Ultralong room temperature phosphorescence (URTP) emitted from pure amorphous organic molecules is very rare. Although a few crystalline organic molecules could realize URTP with long lifetimes (>100 ms), practical applications of these crystalline organic phosphors are still challenging because the formation and maintenance of high-quality crystals are very difficult and complicated. Herein, we present a rational design for minimizing the vibrational dissipation of pure amorphous organic molecu  ...[more]

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