无压烧结Ca_3(PO_4)_2/Si_3N_4复合陶瓷的组织结构与性能

以Ca3(PO4)2和Si3N4为原料,采用无压烧结的方法制备Ca3(PO4)2/Si3N4系列复合陶瓷。复合材料中Ca3(PO4)2能与Si3N4稳定共存,烧结后未发现有新相生成。随着烧结温度的提高,复合材料的致密度和β-Si3N4的相对含量也随之升高,柱状β-Si3N4晶粒的生长更加充分,晶粒相互搭接、交织。复合陶瓷的力学性能随着烧结温度的提高而升高,1700℃无压烧结复合材料的抗弯强度达到547MPa,断裂韧性达到7.3MPa.m1/2,从断口照片中可以观察到β-Si3N4晶粒的拔出和桥联作用。通过加热试样并在水中骤冷后测弯曲强度的方法,表明Ca3(PO4)2/Si3N4复合材料具有良好的抗热震性能。

Ce^(3+)/Eu^(2+)共掺Ca_3Si_2O_4N_2荧光粉的光学特性

采用高温固相法制备了一种新型的白光LED用Ca3Si2O4N2∶Eu2+,Ce3+,K+荧光粉。利用X射线衍射仪对样品的物相结构进行了分析,结果表明:Ce3+和K+离子的掺杂没有改变Ca3Si2O4N2∶Eu2+荧光粉的主晶相。利用荧光光谱仪对样品的发光性能进行了测试,发现样品在355 nm激发下得到的发射光谱为峰值位于505 nm的单峰,是Eu2+离子5d-4f电子跃迁引起的。Ca3Si2O4N2∶Eu2+荧光粉通过Ce3+和K+离子的掺杂,发光明显增强。当Ce3+的摩尔分数为1%时,荧光粉的发光强度达到最大值,是单掺Eu2+离子荧光粉发光强度的168%。通过光谱重叠的方法计算Ce3+→Eu2+能量传递临界的距离为2.535 nm。

Synthesis of a Novel Bluish-Green Emitting Oxynitride Ca₃Al₈Si₄O₁₇N₄:Eu²⁺Phosphor in a CaAl_4-xSi_xO_7-xN_xSolid Solution System

Synthesis of oxynitride solid solutions CaAl4-xSixO7-xNx:Eu2+ (x = 0 - 4) was attempted by the solid state reaction (SSR) methods using Si3N4 and AlN as nitrogen sources. The Ca3Al8Si4O17N4 (x = 4/3) sample with the high phase purity was obtained when AlN was used as a nitrogen source whereas the sample synthesized using Si3N4 as another nitrogen source contained a Ca2Al2SiO7 impurity. Thus, it was revealed that AlN was a preferable nitrogen source for the synthesis of Ca3Al8Si4O17N4 by the SSR method. The solid solutions around x = 4/3 activated with Eu2+ exhibited bluish-green luminescence with emission maxima at 480 nm by the excitation at 250 - 450 nm. Thus, the CaAl4-xSixO7-xNx: Eu2+ solid solutions especially for Ca3Al8Si4O17N4:Eu2+ (x = 4/3) were developed as novel

金属间化合物Ca_3Si_4光学性质的第一性原理计算

使用基于密度泛函理论的第一性原理赝势平面波方法,对Ca3Si4块体进行了详细的计算研究,得到了金属间化合物Ca3Si4是一种间接带隙半导体,禁带宽度为0.372 eV;价带主要由Si的3s和3p态电子构成,导带主要由Ca的3d态电子构成。其光学性质结果为:静态介电常数为19,折射率为4.35,吸收系数最大峰值为1.56×105cm-1,能量损失峰的最大值约在8.549 eV处。