(Y,Gd)BO_3∶Eu^(3+)荧光粉的合成及粒度控制

使用草酸共沉淀法合成了钇钆铕氧化物生粉,以此为原料合成了PDP用(Y,Gd)BO3∶Eu3+荧光粉;研究了各种因素对(Y,Gd)BO3∶Eu3+荧光粉相对亮度及粒度的影响。结果表明,加入适当的添加剂可以有效控制荧光粉的粒度和颗粒形貌,但加入量过多会影响荧光粉的亮度;温度、保温时间、预烧、硼酸配比等参数均对荧光粉度及粒度有较大影响。给出了优化的工艺参数,按此工艺可以直接合成粒度2～4μm的荧光粉,无须球磨分散。在λex=147nm激发时,该荧光粉色坐标x=0.644,y=0.356。

均一球形PDP用荧光粉(Y,Gd)BO_3∶Eu的合成

利用共沉淀法通过控制稀土离子浓度、沉淀温度等得到稀土氧化物前驱体沉淀,再将其和H3BO3 按化学计量比混合煅烧制备出了平均粒径在 0. 5~1. 0μm的球形、粒径分布较小和无团聚的 (Y,Gd)BO3∶Eu荧光粉,其性能在一些方面优于商用荧光粉。利用X射线衍射、SEM、粒度分析仪和PL光谱进行表征。研究了不同的煅烧温度对荧光粉性能的影响,结果发现用本实验方法在 800 ℃煅烧即可得到纯相的(Y,Gd)BO3∶Eu。而传统固相合成纯相的(Y,Gd)BO3∶Eu反应温度高达 1 200℃。因本方法工艺较易控制,适于在工业生产上推广。

Li_2CO_3-NaCl复合助熔剂对(Y,Gd)BO_3:Eu荧光粉合成的影响

在合成(Y,Gd)BO3:Eu的过程中,通过加入适量助熔剂制备出了颗粒小、颗粒形貌为球形、粒径分布较窄和分散性好无团聚的(Y,Gd)BO3:Eu荧光粉,探讨了在焙烧时添加复合助熔剂对荧光粉的最低烧成温度、粒径、颗粒形貌和相对亮度的影响,利用X射线衍射、扫描电镜(SEM)、粒度分析仪和辐射光谱仪对样品进行了表征.结果显示:复合助熔剂的添加,可降低高温固相反应温度,促进硼酸盐纯相的生成,在800℃即可得到纯的(Y,Gd)BO3:Eu相,比未添加助熔剂的反应温度降低了400℃,同时有利于(002)、(100)、(102)、(110)的生长;在(Y,Gd)BO3:Eu的烧结过程中,产生黏度较低的液相有利于球形颗粒的生长,易得到颗粒尺寸分布均匀,分散性好,结晶完整的荧光粉;助熔剂的添加可以使(Y,Gd)BO3:Eu的相对发光强度提高10%以上.用此方法合成的荧光粉具备了直接实际应用的条件.

助熔剂硼酸对红色荧光粉(Y,Gd)BO_3:Eu^(3+)结构及发光性能的影响

以Y_2O_3、Gd_2O_3、Eu_2O_3和H_3BO_3为原料,草酸为沉淀剂,采用共沉淀法合成了PDP用红色荧光粉(Y,Gd)BO_3:Eu^(3+)。着重研究了H_3BO_3作助熔剂对荧光粉(Y,Gd)BO_3:Eu^(3+)结构、发光性能、平均粒径和形貌的影响。结果表明,添加过量的H_3BO_3作助熔剂有利于荧光粉的晶化,能提高荧光粉的相对发光强度,减小荧光粉的平均粒径,同时还能使颗粒变得均匀;H_3BO_3的最佳补偿量为3%。

PDP用球形荧光粉(Y,Gd)BO_3:Eu的研究

采用超声波雾化和高温烧结相结合的方法合成了(Y,Gd)BO_3:Eu荧光粉,考察了分散剂、分散剂用量、合成温度对粉体形貌的影响.研究结果表明:以氨水和柠檬酸作分散剂,柠檬酸的用量为r(柠檬酸)=0.1,控制溶液的pH为4～5,在1000℃下合成,得到了亮度高、实心、球形的荧光粉颗粒,并且经二次热处理后粉体形貌不发生变化.

Coating Nano-Hematite on (Y, Gd)BO_3∶Eu ^(3+) Phosphors by A Facile Method

(Y, Gd)BO_3∶Eu 3+ particles coated with nano-hematite were prepared by a facile method, for example (humid) solid phase reaction at room temperature. The resulted hematite-coated (Y,Gd)BO_3∶Eu 3+ particles were characterized by scanning electron microscopy (SEM), energy dispersive spectrometer (EDS) analysis, X-ray diffraction (XRD), X-ray photoelectron spectra (XPS), and photoluminescence spectra (PL). The SEM and EDS analyses indicate that the particles are coated with a very thin layer of iron oxide. XPS results further confirmed that the coating was hematite, and the coating thickness was in nanometer range. XRD patterns showed that either the hematite coating was too thin or the content of hematite was too small, so that the XRD cannot detect it. The emission spectra illustrate that the peak near 580 nm disappears due to the coating of iron oxide, and when the coating is very thin, the ratio of 5D_0→7F_2 to 5D_0→7F_1 of coated particles is higher than that of uncoated ones, which indicates that the color purity of the phosphor is increased by coating nano-hematite.