放射发光
材料科学
声子
闪烁体
猝灭(荧光)
光电子学
发光
Crystal(编程语言)
消散
热的
辐射传输
陶瓷
能量(信号处理)
光致发光
闪烁
晶体缺陷
单晶
活化能
化学物理
能量转移
无辐射复合
凝聚态物理
作者
Chengyu Qian,Yujie Deng,Qian Wang,Youkui Xu,Jiaheng Zhang,Guoqiang Peng,Shusheng Li,Dun Yuan,Zhipeng Ci,Zhiwen Jin
标识
DOI:10.1021/acsami.5c18858
摘要
In deep-earth environments, glass scintillators (GSs) can better withstand high temperature (>200 °C), high-humidity and other extreme conditions compared to crystal scintillators. However, due to their inherently high phonon energy and abundant defects, GSs are prone to thermal quenching (TQ), resulting in a low detection efficiency at elevated temperatures. To suppress TQ at high temperatures, an investigation into the mechanism of phonons and defects in the radioluminescence is conducted by introducing fluorides to create a low phonon environment and nanocrystallization to regulate a high proportion of shallow defect states. It is revealed that lower phonon energy effectively reduces energy dissipation during hot carrier relaxation, while shallow defect states facilitate carrier transport efficiency during migration to luminescent centers. Two strategies thereby collectively enhance radiative recombination. Based on the above, Al4B2O9:Tb3+ glass ceramic (GC) with a lower phonon energy and dominant shallow defect states (0.74 eV) was successfully synthesized. It has achieved excellent anti-TQ performance (188% at 400 °C), high spatial resolution (20 lp mm–1) and X-ray induced time-lapse imaging. This result has paved new avenues for GSs for applications in deep-earth environments.
科研通智能强力驱动
Strongly Powered by AbleSci AI