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西安工业大学 材料与化工学院,陕西 西安,710032
纸质出版日期:2012-11-10,
收稿日期:2012-7-30,
修回日期:2012-9-1,
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单民瑜, 陈卫星, 王丽玲, 刘秀兰. 煅烧温度对Cu掺杂ZnO纳米粉体的制备及发光性能的影响[J]. 发光学报, 2012,(11): 1204-1208
SHAN Min-yu, CHEN Wei-xing, WANG Li-ling, LIU Xiu-lan. Effect of Calcination Temperature on Preparation and Luminescent Properties of Cu Doped ZnO Nano-powder[J]. Chinese Journal of Luminescence, 2012,(11): 1204-1208
单民瑜, 陈卫星, 王丽玲, 刘秀兰. 煅烧温度对Cu掺杂ZnO纳米粉体的制备及发光性能的影响[J]. 发光学报, 2012,(11): 1204-1208 DOI: 10.3788/fgxb20123311.1204.
SHAN Min-yu, CHEN Wei-xing, WANG Li-ling, LIU Xiu-lan. Effect of Calcination Temperature on Preparation and Luminescent Properties of Cu Doped ZnO Nano-powder[J]. Chinese Journal of Luminescence, 2012,(11): 1204-1208 DOI: 10.3788/fgxb20123311.1204.
在PVA溶液中制备ZnO:Cu纳米粉体的前驱体
经过煅烧获得ZnO:Cu纳米粉体
考察煅烧温度对制备过程及发光性能的影响。利用XRD、 TEM分析了产物的结构和形貌
XRD分析结果表明
当煅烧温度高于500℃时
可以使PVA完全分解
制备出具有六角纤锌矿结构的ZnO:Cu粉体。TEM结果表明
粉体呈球形
大小均匀
分散性好
平均粒径为20~25 nm。在342 nm波长光的激发下
在ZnO:Cu的室温PL光谱中可以观察到两个中心波长位于458 nm和486 nm的较强的蓝光发射峰
经400℃煅烧处理的ZnO:Cu纳米粉体的蓝光发射最强。煅烧后的ZnO:Cu只有微弱的绿光发射(510~530 nm)
Cu的掺杂使ZnO的绿光发射变为蓝光发射。蓝紫光的发射波长随煅烧温度的升高产生明显的红移
由300℃时的404 nm红移至600℃时的422 nm
发射强度随温度升高先增大后减小。
The precursors of ZnO:Cu nano-powder were prepared in PVA aqueous solution. Then the products were obtained by calcining with different temperature. The effect of calcination tempe-rature on preparation and the photoluminescence of the ZnO:Cu nano-powder was investigated. The products dealed with different temperature were characterized by XRD
TEM and PL. The results of XRD indicated that when the clacination temperature was above 500℃
the products had a crystal structure of hexagonal wurtzite
while the polymer PVA decomposed completely. The TEM result showed that the nano-powder was spherical with a uniform size of 20~25 nm and good dispersibility. Two blue emission peaks centered at 458 nm and 486 nm were observed in the room temperature PL spectra excited with 342 nm light. The product calcined in 400℃ had the most strongest blue emission
while the green emissions (510~530 nm) became weak and changed into blue emission. With the clacination temperature increasing
the violet-blue spectral had an obvious red shift from 404 nm to 422 nm. The emission intensity increased firstly and then decreased.
氧化锌掺杂聚乙烯醇煅烧温度光致发光
zinc oxidedopingPVAcalcination temperaturephotoluminescence
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