原子能级粒子数热布局虚拟仿真实验的设计开发与教学实践

本虚拟仿真实验探究稀土离子热耦合能级粒子数随温度的变化规律。使学生掌握温度对原子能级粒子数的影响,并建立温度与荧光强度、荧光强度比之间的关系,深入探究温度对荧光强度和荧光强度比影响的区别和联系,加强对此部分理论知识的理解。进一步将理论知识进行实际应用,利用荧光强度比测量温度。通过本实验的学习,使学生对原子能级性质的理解更加深刻、掌握正确的荧光测试系统搭建过程,光路调节方法以及光谱数据的计算分析方法。激发了学生的学习兴趣,夯实了理论基础,并能学以致用,使学生对知识理解透彻,获得事半功倍的教学效果,仿真实验成绩优秀率达81%。

荧光热增强型稀土掺杂上转换发光材料研究进展

稀土掺杂上转换发光材料的荧光强度通常会随着温度上升而呈现明显的热猝灭现象,这对其在温度传感、防伪、显示等方面的应用产生了极大的障碍。最近,研究人员在实验中发现了上转换发光强度随温度升高而增强的特殊现象,并开展了大量工作揭示其内在机理以及可能影响热增强效应的因素。上转换热增强效应的机理探究和优化对于未来开发新型的稀土上转换发光材料提供了新颖的思路,也为稀土上转换发光材料的应用研究奠定了基础。本文对荧光热增强型稀土掺杂上转换发光材料的最新研究进展进行了简单总结和梳理,主要介绍了荧光热增强效应的内在机理以及潜在应用,并展望了未来研究中所面临的机遇和挑战。

基于Er^(3+)的力致温度传感

近年来,力致发光(ML)材料引起了科研人员的广泛关注,因其在众多领域特别是温度传感领域具有潜在的应用价值.值得注意的是,基于ML的温度传感尚处于萌芽期,且目前没有理论支持.本文中,我们基于CaZnOS:Er^(3+)力致发光材料和玻尔兹曼分布建立了ML温度传感技术的理论框架.在外部应力刺激下,CaZnOS:Er^(3+)力致发光材料能够发射出明亮的绿色荧光,且遵从玻尔兹曼分布理论.基于此,我们证实了该ML温度传感理论框架的适用性,并将其应用到实际案例中,即监测水壶的温度.与此同时,我们也开发了CaZnOS:Er^(3+)力致发光材料的多重功能,验证了其在动态防伪和信息加密提取方面的应用.简言之,本工作从实验和理论两方面进行研究,奠定了ML温度传感技术实用化的基础.

MgF_(2):Mn^(2+):novel material with mechanically-induced luminescence

Mechanoluminescent(ML)materials can directly convert external mechanical stimulation into light without the need for excitation from other forms of energy,such as light or electricity.This alluring characteristic makes ML materials potentially applicable in a wide range of areas,including dynamic imaging of force,advanced displays,information code,storage,and anti-counterfeiting encryption.However,current reproducible ML materials are restricted to sulfide-and oxide-based materials.In addition,most of the reported ML materials require pre-irradiation with ultraviolet(UV)lamps or other light sources,which seriously hinders their practical applications.Here,we report a novel ML material,MgF_(2):Mn^(2+),which emits bright red light under an external dynamic force without the need for pre-charging with UV light.The luminescence properties were systematically studied,and the piezophotonic application was demonstrated.More interestingly,unlike the well-known zinc sulfide ML complexes reported previously,a highly transparent ML film was successfully fabricated by incorporating MgF_(2):Mn^(2+)into polydimethylsiloxane(PDMS)matrices.This film is expected to find applications in advanced flexible optoelectronics such as integrated piezophotonics,artificial skin,athletic analytics in sports.