Gd_(2)O_(2)S:Tb闪烁陶瓷的制备与结构:水浴合成中H_(2)SO_(4)/Gd_(2)O_(3)摩尔比的影响

Gd_(2)O_(2)S:Tb闪烁陶瓷以其明亮的绿色发光、高能量转换效率和高中子俘获截面而广泛应用于中子成像和工业无损检测等领域,但Gd_(2)O_(2)S:Tb陶瓷中存在的Gd_(2)O_(3)第二相影响其闪烁性能。本工作以H_(2)SO_(4)和Gd_(2)O_(3)为原料,采用水浴法合成Gd_(2)O_(2)S:Tb前驱体,研究了H_(2)SO_(4)与Gd_(2)O_(3)的摩尔比(n)对前驱体和Gd_(2)O_(2)S:Tb粉体性能的影响。前驱体的化学组成随n增大而变化:2Gd_(2)O_(3)·Gd_(2)(SO_(4))_(3)·xH_(2)O(n<2.00)、Gd_(2)O_(3)·2Gd_(2)(SO_(4))_(3)·xH_(2)O(2.25≤n≤2.75)和Gd_(2)(SO_(4))_(3)·8H_(2)O(n=3.00),经过空气煅烧和氢气还原后,所有的粉体均形成Gd_(2)O_(2)S相。Gd_(2)O_(2)S:Tb粉体的形貌与前驱体的相组成密切相关,随着n增大,Gd_(2)O_(2)S:Tb粉体的XEL强度增加呈现出两个阶段,对应前驱体的相转变阶段。采用真空预烧结合热等静压烧结制备了Gd_(2)O_(2)S:Tb陶瓷,相较于n为2.00、2.25、2.50,其他n制备的Gd_(2)O_(2)S:Tb陶瓷都达到了较高的相对密度和XEL强度,不同n制备的陶瓷中都存在Gd_(2)O_(3)第二相,n增大有利于减少陶瓷内部的第二相,为进一步消除Gd_(2)O_(2)S:Tb陶瓷中的第二相提供了思路。

Gd_(2)O_(2)S:Tb^(3+)荧光粉的晶体形貌改善研究

研究人员利用高温固相法,通过添加多种助熔剂合成了Gd_(2)O_(2)S:Tb^(3+)荧光粉,并提出了一种新的后处理工艺。利用X射线衍射(XRD)、扫描电子显微镜(SEM)和荧光光谱(PL)对荧光粉产物进行物相、形貌及发光性能的表征。结果表明,经过后处理的Gd_(2)O_(2)S:Tb^(3+)荧光粉晶体形貌饱满,粒度均匀度高,D50=10μm,PL谱呈现Tb3+的特征发射峰,最强峰为547 nm的绿色发射峰,并且具有高亮度。

稀土离子掺杂Gd_(2)O_(2)S闪烁陶瓷的研究进展

稀土离子掺杂Gd_(2)O_(2)S闪烁陶瓷是20世纪80年代以后发展的硫氧化物闪烁体。高密度和高热中子吸收截面的Gd_(2)O_(2)S基质具有高的X射线和热中子阻止能力,稀土离子(Pr^(3+)、Tb^(3+)等)的掺杂使其表现出快衰减或高光产额等特性,在闪烁领域的应用中占据着重要地位。硫氧化合物的组分控制一直是其合成过程中需要解决的关键问题,Gd_(2)O_(2)S材料的高熔点和S元素挥发严重的问题,限制了高光学质量和优良闪烁性能单晶的制备,因此陶瓷是Gd_(2)O_(2)S闪烁体的主要应用形式。颗粒小、粒径分布窄且低团聚的纯相Gd_(2)O_(2)S粉体是高质量闪烁陶瓷烧结的关键,单纯提高烧结温度制备的Gd_(2)O_(2)S闪烁陶瓷会产生大量的硫空位和氧空位,降低材料的闪烁性能。制备Gd_(2)O_(2)S闪烁陶瓷通常需要压力辅助烧结,这种苛刻的制备条件提高了生产成本。本文介绍了闪烁体的闪烁机理及研究概况,着重综述了Gd_(2)O_(2)S闪烁陶瓷的制备工艺、缺陷的解决方法以及在中子成像和医学X-CT领域的研究现状及应用情况,最后对全文进行总结并对Gd_(2)O_(2)S闪烁陶瓷发展前景进行了展望。

A sandwiched luminescent heterostructure based on lanthanide-doped Gd_(2)O_(2)S@NaYF_(4)core/shell nanocrystals

Lanthanide(Ln^(3+))oxysulfide nanocrystals(NCs)have great prospect in many advanced technologies;however,they suffer from a low photoluminescence efficiency due to the volatility of sulfur and deleterious surface quenching effect.Herein,we report a novel sandwiched luminescent heterostructure based on Ln^(3+)-doped Gd_(2)O_(2)S@NaYF_(4)core/shell NCs with tunable sulfur content in the sandwich layer.By means of Eu^(3+)as the sensitive structural probes,we unravel the ligand-mediated structure control of the NCs from Gd_(2)O_(3):Ln^(3+)@NaYF_(4)to Gd_(2)O_(2)S:Ln^(3+)@NaYF_(4)with tailored S2–deficiency.Such a sandwich-type core/shell heterostructure enables us to achieve efficient and multicolor downshifting and upconversion luminescence(UCL),with up to 208.8 folds of enhancement in UCL intensity as compared to that of their core-only counterparts.These findings provide a general approach for the controlled synthesis of lanthanide oxysulfide@fluoride heterostructure,which offers a new way for the materials design towards diverse emerging applications.