超声波辅助合成YOF:Tb^(3+)荧光粉及其荧光性能

以Tb4O7与Y2O3为主要原料,用超声波辅助合成前驱体,经高温煅烧后合成了稀土YOF:Tb3+绿色荧光粉。采用XRD、SEM和荧光分光光度计对样品的结构、形貌和荧光性能进行分析。样品XRD表明,产物为四方晶系YOF:Tb3+,结晶度较好。SEM表明合成的荧光粉为100mm^200nm左右的纳米颗粒。荧光分析显示,荧光粉的荧光性能受前驱体辅助合成方式及Tb3+掺杂浓度等各种因素影响。在230nm的紫外光激发下,40℃的低温超声波辅助下合成的前驱体经过煅烧后制得的荧光粉荧光性效果好。当Tb3+的摩尔掺杂浓度大于5%时,出现浓度淬灭现象。

Yb^(3+)/Er^(3+)共掺杂纳米YOF体内外发光性能研究

为实现YOF纳米颗粒在体内外的高性能荧光发射及造影,采用共沉淀法设计制备了YOF∶Yb^(3+)/Er^(3+)纳米颗粒,并对其相结构、显微形貌、上转换荧光性质以及体内外荧光成像效果进行了测试。结果表明,该纳米颗粒的尺寸约为50 nm,且形貌介于六边形与圆形之间;在980 nm激光激发下可发射黄绿光,其上转换荧光光谱红绿比为3.287;在体内外可分别实现良好的上转换荧光发射及梯度荧光成像效果。

共沉淀法制备YOF:Yb^(3+),Er^(3+)造影颗粒的发光性能及正交优化

为了优化YOF:Yb^(3+),Er^(3+)纳米颗粒的发光性能,并促进其荧光造影能力,以YOF为基质、Yb^(3+)和Er^(3+)为掺杂离子,采用共沉淀法合成了纳米晶。通过正交试验和色品分析,筛选适合纯色、高荧光发射强度的制备工艺。结果表明,YOF:Yb^(3+),Er^(3+)纳米颗粒的TEM显微形貌界于圆形与蜂窝型之间,其尺寸约为50 nm。在980 nm激光照射下,其荧光发射红绿比较高。利用正交试验和色品分析水浴温度、煅烧时间及KF添加量三因素,最终确定在85℃水浴、煅烧1 h和1 mol KF条件下制备的试样最符合红光造影剂的性能要求。

钬离子掺杂氟氧钇亚微米晶的荧光量子化表征与温度传感特性研究

采用水热合成法和高温煅烧法相结合制备了Ho^(3+)/Yb^(3+)共掺杂三方晶系的YOF亚微米晶体,该晶体具有较强的量子产率和良好的灵敏度。在977 nm激光泵浦下对晶体颗粒的上转换发光性能进行表征,利用荧光光谱测试系统绘制出样品的光谱功率分布。计算了光量子数分布和量子产率等绝对荧光参量。展示了在303~433 K温度范围内的荧光上转换发光性能并计算了灵敏度。测试结果表明,在977 nm激光激发下泵浦功率密度为73 m W/mm~2时,总光通量达到3.35 mlm,Ho^(3+)的绿光和红光的量子产率分别为2.97×10^(-5)和1.40×10^(-5),较高的量子产率确保了足够的荧光强度来实现温度反馈。在303 K时有最大相对灵敏度为0.437%K^(-1),当温度升至433 K时相对灵敏度仍能保持在0.331%K^(-1)。因此Ho^(3+)/Yb^(3+)共掺杂YOF亚微米晶体作为一种高效发光和高温度灵敏度材料为温度传感领域提供了一种潜在的选择。

Improved electrochemical performances of yttrium oxyfluoride-coated Li[Li0.2Mn0.54Ni0.13Co0.13]O2 for lithium ion batteries

The Li-rich layered oxides show a higher discharge capacity over 250 mAh/g and have been developed into a promising positive material for lithium ion batteries. A rare earth metal oxyfluoride YOF-coated Li[Lio.2Mno.54Ni0.13Co0.13]O2 composites have been synthesized by a simple wet chem- ical method. Crystal structure, micro-morphology and element valence of the pristine and YOF-coated Li[Li0.2Mn0.54Ni0.13Co0.13]O2 materials are characterized by XRD, SEM, TEM, and XPS. The results indicate that all materials exhibit a typical layered structure, and are made up of small and homogenous parti- cles ranging from 100 nm to 200 nm. In addition, YOF layer with a thickness of approximately 3-8 nm is precisely coated on the surface of the Li[Li0.2Mn0.54Ni0.13Co0.13]02. Constant current charge/discharge tests at various current densities show that the electrochemical performance of 2 wt% YOF-coated Li[Li0.2Mn0.54Ni0.13Co0.13]O2 has been improved significantly. 2 wt% YOF-coated Li[Li0.2Mn0.54Ni0.13Co0.13]O2 delivers the highest discharge capacity of 250.4 mAh/g at 20 mA/g among all the samples, and capacity retention of 87% after 100 charge/discharge cycles at 200 mA/g while that of the pristine one is only 81.6%. The superior electrochemical performance of 2wt% YOF-coated sample is ascribed to YOF coating layer, which could not only reduce side reactions between the electrode and liquid electrolyte, but also promote lithium ion migration.

球形碱式碳酸钇的制备及其氟化转型合成氟氧化钇的研究

用尿素作沉淀剂,采取均相沉淀法合成球形YOHCO_(3)·nH_(2)O前驱体,考察了尿素浓度、氯化钇浓度、pH、反应温度、反应时间、冷却及干燥方式对前驱体形貌的影响,以氟化铵为氟源,经氟化焙烧合成了球形YOF。结果表明,尿素浓度为1 mol/L,氯化钇浓度为0.01 mol/L,pH=4的初始溶液在85℃的水浴中反应2 h,经冰水淬冷、鼓风干燥获得D_(50)粒径为427 nm的均匀球形前驱体YOHCO_(3)·nH_(2)O;前驱体在30℃下氟化转型并在800℃下焙烧2 h后,获得粒径分布范围为150 nm~300 nm的球形YOF六方相。