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V形坑尺寸对硅衬底InGaN/AlGaN近紫外LED光电性能的影响 被引量:3

Effect of V-pit Size on Optical and Electrical Properties of InGaN/AlGaN Near-ultraviolet Light Emitting Diode
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摘要 使用MOCVD在图形化Si衬底上生长了InGaN/AlGaN近紫外LED,通过改变低温GaN插入层的厚度调控V形坑尺寸,系统地研究了V形坑尺寸对InGaN/AlGaN近紫外LED(395 nm)光电性能的影响。结果表明,低温GaN插入层促进了V形坑的形成,并且V形坑尺寸随着插入层厚度的增加而增大。在电学性能方面,随着V形坑尺寸的增大,-5 V下的漏电流从5.2×10^(-4)μA增加至6.5×10~2μA;350 mA下正向电压先从3.55 V降至3.44 V,然后升高至3.60 V。在光学性能方面,随着V形坑尺寸的增大,35 A/cm^2下的归一化外量子效率先从0.07提高至最大值1,然后衰退至0.53。对V形坑尺寸影响InGaN/AlGaN近紫外LED光电性能的物理机理进行了分析,结果表明:InGaN/AlGaN近紫外LED的光电性能与V形坑尺寸密切相关,最佳的V形坑尺寸为120~190 nm,尺寸太大或者太小都会降低器件性能。 InGaN/AlGaN near-ultraviolet light emitting diode (near-UV LED) were grown on pat- terned Si substrate by metal-organic chemical vapor deposition (MOCVD). The effects of V-pit size on optical and electrical properties of InGaN/A1GaN near-UV LED (395 nm) were investigated systematically by manipulating the thickness of low temperature GaN interlayer to change the V-pit size. The results show that the low temperature GaN interlayer can enhance the formation of V-pit, and the V-pit size increases with the increasing of the thickness of low temperature GaN interlayer. In terms of electrical properties, with the increasing of the V-pit size, the leakage current at - 5 V increases from 5.2 × 10^-4 μA to 6.5 × 10^2 μA, and the forward voltage at 350 mA decreases from 3.55 V to 3.44 V initially and then increases to 3.60 V. In terms of optical properties, with the in- creasing of the V-pit size, the normalized external quantum efficiency (EQE) at 35 A/cm2increases from 0.07 to the maximum of 1 initially and then decreases to 0.53. The mechanism of the effects of V-pit size on optical and electrical properties of InGaN/A1GaN near-UV LED were analyzed. The analyzing results show that the optical and electrical properties of InGaN/A1GaN near-UV LED are closely related to V-pit size. The optimized V-pit size is approximately 120 -190 nm, too large or too small will deteriorate the properties of devices seriously.
作者 聂晓辉 王小兰 莫春兰 张建立 潘拴 刘军林
机构地区 南昌大学国家硅基LED工程技术研究中心
出处 《发光学报》 EI CAS CSCD 北大核心 2017年第6期735-741,共7页 Chinese Journal of Luminescence
基金 国家自然科学基金青年基金(21405076)资助项目~~
关键词 硅衬底 近紫外LED 低温GaN插入层 V形坑尺寸 光电性能 Si substrate near-UV LED low temperature GaN interlayer V-pit size optical and electrical properties
分类号 O484.4 [理学—固体物理] TN383.1 [电子电信—物理电子学]
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发光学报
2017年 第6期

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