发光学报
髮光學報
발광학보
CHINESE JOURNAL OF LUMINESCENCE
2010年
5期
613-618
,共6页
张侠%刘渝珍%康朝阳%徐彭寿%王家鸥%奎热西
張俠%劉渝珍%康朝暘%徐彭壽%王傢鷗%奎熱西
장협%류투진%강조양%서팽수%왕가구%규열서
ZnO薄膜%快速退火%光致发光%X射线光电子能谱%氧空位
ZnO薄膜%快速退火%光緻髮光%X射線光電子能譜%氧空位
ZnO박막%쾌속퇴화%광치발광%X사선광전자능보%양공위
thin ZnO films%rapid thermal annealing%photoluminescence%XPS%oxygen vacancies
采用脉冲激光沉积技术在Si/蓝宝石衬底上制备了ZnO薄膜,结合快速退火设备研究了不同退火温度(500~900℃)及退火气氛(N2O2)对薄膜的结构及其发光性能的影响.并优化条件得到具有最小半峰全宽及最大晶粒尺寸的薄膜.X射线衍射(XRD)结果表明:氮气氛下退火的ZnO薄膜最佳退火温度为900℃;氧气氛下退火的ZnO薄膜最佳退火温度为800℃.红外(IR)光谱中,退火后Zn-O特征振动峰红移,说明在退火过程中,原子重新排布后占据较低能量位置;同样的退火温度下,氮气氛下退火的薄膜质量更优.同步辐射光电子能谱(synchrotron-based XPS)分别表征了未退火及N2O2:下900℃退火的ZnO薄膜,分峰拟合结果表明氧气氛下退火产生更多的氧空位.结构表征结合光致发光(PL)谱表明绿光的发光峰与氧空位有关.
採用脈遲激光沉積技術在Si/藍寶石襯底上製備瞭ZnO薄膜,結閤快速退火設備研究瞭不同退火溫度(500~900℃)及退火氣氛(N2O2)對薄膜的結構及其髮光性能的影響.併優化條件得到具有最小半峰全寬及最大晶粒呎吋的薄膜.X射線衍射(XRD)結果錶明:氮氣氛下退火的ZnO薄膜最佳退火溫度為900℃;氧氣氛下退火的ZnO薄膜最佳退火溫度為800℃.紅外(IR)光譜中,退火後Zn-O特徵振動峰紅移,說明在退火過程中,原子重新排佈後佔據較低能量位置;同樣的退火溫度下,氮氣氛下退火的薄膜質量更優.同步輻射光電子能譜(synchrotron-based XPS)分彆錶徵瞭未退火及N2O2:下900℃退火的ZnO薄膜,分峰擬閤結果錶明氧氣氛下退火產生更多的氧空位.結構錶徵結閤光緻髮光(PL)譜錶明綠光的髮光峰與氧空位有關.
채용맥충격광침적기술재Si/람보석츤저상제비료ZnO박막,결합쾌속퇴화설비연구료불동퇴화온도(500~900℃)급퇴화기분(N2O2)대박막적결구급기발광성능적영향.병우화조건득도구유최소반봉전관급최대정립척촌적박막.X사선연사(XRD)결과표명:담기분하퇴화적ZnO박막최가퇴화온도위900℃;양기분하퇴화적ZnO박막최가퇴화온도위800℃.홍외(IR)광보중,퇴화후Zn-O특정진동봉홍이,설명재퇴화과정중,원자중신배포후점거교저능량위치;동양적퇴화온도하,담기분하퇴화적박막질량경우.동보복사광전자능보(synchrotron-based XPS)분별표정료미퇴화급N2O2:하900℃퇴화적ZnO박막,분봉의합결과표명양기분하퇴화산생경다적양공위.결구표정결합광치발광(PL)보표명록광적발광봉여양공위유관.
Thin ZnO films were grown on silicon (111)/sapphire substrate via pulsed laser deposition technique and then some of the samples were treated with different rapid thermal annealing (RTA) conditions, such as annea-ling temperature ranging of 500 to 900 ℃ and annealing ambience (nitrogen and oxygen). Finally, these samples were characterized with X-ray diffraction (XRD), X-ray photoelectron spectroscopy (XPS), IR and photolumines-cence (PL), respectively. It was observed that the quality and the grain size of thin ZnO films increased after annea-ling. Moreover, at the same lower annealing temperature, the films annealed under nitrogen ambience showed better qualities and few oxygen vacancies than those annealed under oxygen ambience. The experiment showed that the best annealing temperature under nitrogen ambience was 900 ℃ and the optimum annealing temperature under oxygen ambience was 800 ℃. Furthermore, as oxygen vacancies decreased, stronger green photoluminescence was detected, possibly related to the contents of the oxygen vacancies.