材料科学
持续发光
发光
兴奋剂
红外线的
钛酸钙
钛酸酯
光电子学
窗口(计算)
荧光粉
纳米技术
光学
陶瓷
电介质
物理
复合材料
操作系统
热释光
计算机科学
作者
Gulizhabaier Abulipizi,Juanjuan Zhou,Chaomin Qu,Leping Ding,Ziang Zong,Yanlun Fang,Z. Yu,Xingyuan Shi,Fanwen Yang,Zhanjun Li
标识
DOI:10.1021/acsami.5c07800
摘要
Lanthanide-doped materials were developed with interesting near-infrared (NIR) persistent luminescence (PersL) properties after X-ray irradiation but are limited by poor charging ability based upon biocompatible red light. In this study, CaTiO3:Tm (CTT) was found to emit an unusual single band PersL at ∼800 nm, which was rechargeable by red-NIR light excitation (∼650 to 720 nm). Moreover, blue or deep red light could charge more intense PersL than UV light in CTT, which was quite different from all the other known lanthanide-activated NIR PersL materials. An upconverting-energy transfer PersL mechanism was proposed based on the upconverting property of Tm3+ and its energy transfer to Ti3+ in the CaTiO3 matrix. The interaction of Tm3+ and Ti3+ in CaTiO3 quite possibly played an important role in the unusual PersL process of CTT, which avoided the band-pass transition of the CaTiO3 matrix. By comparison with a series of Tm-doped phosphors, CaTiO3 was found to be an optimal PersL matrix to generate the unique PersL properties of Tm3+. The in situ charged NIR PersL imaging of a medical stent implant in the neck of a chicken model was demonstrated. This study reveals the unusual PersL properties of CTT and will promote advanced biomedical applications of rare-earth-doped PersL biomaterials.
科研通智能强力驱动
Strongly Powered by AbleSci AI