Investigation of InGaN/GaN Nanostructures Using the X-ray Diffraction Techniques

博士 === 國立臺灣大學 === 電機工程學研究所 === 97 === In this dissertation, we utilize X-ray diffraction technique to characterize InGaN/GaN nanostructures. First, we compare the X-ray diffraction (XRD) results of two InGaN/GaN quantum-well (QW) structures to observe the effects of prestrained growth by depositing...

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Main Authors: Wen-Yu Shiao, 蕭文裕
Other Authors: 楊志忠
Format: Others
Language:en_US
Published: 2009
Online Access:http://ndltd.ncl.edu.tw/handle/14876168876168539602
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spelling ndltd-TW-097NTU054420512016-05-04T04:31:31Z http://ndltd.ncl.edu.tw/handle/14876168876168539602 Investigation of InGaN/GaN Nanostructures Using the X-ray Diffraction Techniques 以X-光繞射技術探討氮化銦鎵/氮化鎵奈米結構 Wen-Yu Shiao 蕭文裕 博士 國立臺灣大學 電機工程學研究所 97 In this dissertation, we utilize X-ray diffraction technique to characterize InGaN/GaN nanostructures. First, we compare the X-ray diffraction (XRD) results of two InGaN/GaN quantum-well (QW) structures to observe the effects of prestrained growth by depositing a low-indium QW before the growth of five high-indium QWs. From the results of reciprocal space mapping, we observe the fully strained condition in the QWs of the control sample. However, in the sample of prestrained growth, the average strain is partially relaxed. By using an XRD fitting algorithm for calibrating QW parameters, we obtain reasonable values for the compositions and thicknesses of the QWs in both samples. In particular, by assuming a non-uniform strain relaxation distribution among the five high-indium QWs in the prestrained sample, we obtain reasonable composition variations among the QWs. The high-indium QW closest to the low-indium one is most strain-relaxed and has the highest indium incorporation, leading to the longest-wavelength emission. The observed red shift with increasing electron penetration depth in the cathodo-luminescence spectra of the prestrained sample is consistent with the distributions of calibrated strain relaxation and indium composition. Then, depth-dependent X-ray diffraction techniques are demonstrated. Screw/edge dislocation density and lateral domain size in each depth can be obtained through depth-dependent X-ray diffraction technique. We apply this technique to study the threading dislocation (TD) evolution during coalescence overgrowth on patterned GaN nanocolumn with metalorganic chemical vapor deposition. From the measurement results, it is found that among the overgrowth samples of different nanocolumn diameters and spacing sizes with fixed nanolumn diameter/spacing ration, the one with the smallest size and spacing leads to lowest TD density, the largest lateral domain size, and the highest photoluminescence efficiency. Finally, the dependencies of indium composition and degree of strain relaxation on the growth thickness of an InGaN thin film on GaN near the critical thickness are calibrated based on the measurements of reciprocal space mapping of X-ray diffraction and energy-dispersive X-ray spectroscopy. It is observed that when the growth of InGaN reaches the critical thickness, the hetero-structure-induced strain starts to relax. However, before the degree of strain relaxation reaches ~40 %, the indium composition is fixed at the fully-strained level. Beyond this point, the indium composition increases with growth thickness until the strain becomes fully relaxed. After this point, the indium composition is fixed at this high level. 楊志忠 2009 學位論文 ; thesis 140 en_US
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language en_US
format Others
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description 博士 === 國立臺灣大學 === 電機工程學研究所 === 97 === In this dissertation, we utilize X-ray diffraction technique to characterize InGaN/GaN nanostructures. First, we compare the X-ray diffraction (XRD) results of two InGaN/GaN quantum-well (QW) structures to observe the effects of prestrained growth by depositing a low-indium QW before the growth of five high-indium QWs. From the results of reciprocal space mapping, we observe the fully strained condition in the QWs of the control sample. However, in the sample of prestrained growth, the average strain is partially relaxed. By using an XRD fitting algorithm for calibrating QW parameters, we obtain reasonable values for the compositions and thicknesses of the QWs in both samples. In particular, by assuming a non-uniform strain relaxation distribution among the five high-indium QWs in the prestrained sample, we obtain reasonable composition variations among the QWs. The high-indium QW closest to the low-indium one is most strain-relaxed and has the highest indium incorporation, leading to the longest-wavelength emission. The observed red shift with increasing electron penetration depth in the cathodo-luminescence spectra of the prestrained sample is consistent with the distributions of calibrated strain relaxation and indium composition. Then, depth-dependent X-ray diffraction techniques are demonstrated. Screw/edge dislocation density and lateral domain size in each depth can be obtained through depth-dependent X-ray diffraction technique. We apply this technique to study the threading dislocation (TD) evolution during coalescence overgrowth on patterned GaN nanocolumn with metalorganic chemical vapor deposition. From the measurement results, it is found that among the overgrowth samples of different nanocolumn diameters and spacing sizes with fixed nanolumn diameter/spacing ration, the one with the smallest size and spacing leads to lowest TD density, the largest lateral domain size, and the highest photoluminescence efficiency. Finally, the dependencies of indium composition and degree of strain relaxation on the growth thickness of an InGaN thin film on GaN near the critical thickness are calibrated based on the measurements of reciprocal space mapping of X-ray diffraction and energy-dispersive X-ray spectroscopy. It is observed that when the growth of InGaN reaches the critical thickness, the hetero-structure-induced strain starts to relax. However, before the degree of strain relaxation reaches ~40 %, the indium composition is fixed at the fully-strained level. Beyond this point, the indium composition increases with growth thickness until the strain becomes fully relaxed. After this point, the indium composition is fixed at this high level.
author2 楊志忠
author_facet 楊志忠
Wen-Yu Shiao
蕭文裕
author Wen-Yu Shiao
蕭文裕
spellingShingle Wen-Yu Shiao
蕭文裕
Investigation of InGaN/GaN Nanostructures Using the X-ray Diffraction Techniques
author_sort Wen-Yu Shiao
title Investigation of InGaN/GaN Nanostructures Using the X-ray Diffraction Techniques
title_short Investigation of InGaN/GaN Nanostructures Using the X-ray Diffraction Techniques
title_full Investigation of InGaN/GaN Nanostructures Using the X-ray Diffraction Techniques
title_fullStr Investigation of InGaN/GaN Nanostructures Using the X-ray Diffraction Techniques
title_full_unstemmed Investigation of InGaN/GaN Nanostructures Using the X-ray Diffraction Techniques
title_sort investigation of ingan/gan nanostructures using the x-ray diffraction techniques
publishDate 2009
url http://ndltd.ncl.edu.tw/handle/14876168876168539602
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