Room-temperature phosphorescence (RTP) materials are widely used in bioimaging, information security and lighting because of their distinctive afterglow characteristics.
“Conventional synthesis methods primarily involve inorganic compounds that contain rare-earth ions or complexes containing precious metals to deliver afterglow, which inevitably leads to high biological toxicity and expensive syntheses,” said Dong Wenfei, leading researcher of the study.
Two preconditions must be satisfied before their use, namely efficient exciplex intersystem crossing (ISC), and a stable rigid structure that stabilizes the excited triplet states of the exciplexes, according to Dong.
The team selected 3-Aminopropyl triethoxysilane (APTES) and N-[3-(Trimethoxysilyl) propyl] ethylenediamine (DAMO) as Si sources, with urea added as another precursor, to produce optically stable cyan and yellow RTP materials, respectively.
The one-step hydrothermal method preparation process not only effectively avoids the disadvantages of the two-step method but also more conveniently forms nanodots in situ and immobilizes them in the matrix.
Schematic illustration for the preparations of C-SiNDs@UA, Y-SiNDs@UA, O-SiNDs@UA, and R-SiNDs@UA [IMAGE: SIBET]
This newly-developed anti-counterfeiting strategy can be applied to higher-level encryption scenarios, in which only interference information is obtained in UV-irradiation and afterglow modes, and the assistance of a filter is required to accurately read the encrypted content, thereby enabling better concealment of the correct information, said researchers.
(a) Schematic diagram of the structure of the anti-counterfeiting model (b) Initial code information composed of three materials under 365 nm UV light (5D Code 1) and after removal of the UV light (5D Code 2), and the 5D Code 3, 4, 5 information that changed with time was observed after using the optical filter (λcut-off = 600 nm) [IMAGE: SIBET]
“Given the universality of this method, this standardized strategy not only highlights the potential of constructing multifunctional phosphorescent materials from silane, but also provides a novel design principle for the synthesis of full-color afterglow materials,” said Dr. Zan Minghui, one of the corresponding authors of the study.
“This work demonstrated the feasibility of using silane to synthesize multi-color phosphorescent materials and provides novel design principles and insights for the construction of silicon-based afterglow materials for innovative applications,” said Dong.
The research results entitled “Multi-Color Room Temperature Phosphorescent Silicon-Nanodot-Based Nanocomposites with Silane Tuning and Applications to 5D Information Encryption” were published in Chemical Engineering Journal (IF=15.1).
Liu Yulu is the first author of the paper, and Professor Dong Wenfei and Dr. Zan Minghui are the co-corresponding authors.
For more information, please contact:
Xiao Xintong
E-mail: xiaoxt@sibet.ac.cn
Suzhou Institute of Biomedical Engineering and Technology,
Chinese Academy of Sciences
Source: Suzhou Institute of Biomedical Engineering and Technology,
Chinese Academy of Sciences