基于变温霍尔效应方法的一类n-GaN位错密度的测量

何菊生; 张萌; 潘华清; 邹继军; 齐维靖; 李平

doi:10.7498/aps.66.067201

摘要

结合莫特相变及类氢模型，采用浅施主能量弛豫方法，计算了一类常见n-GaN光电子材料的载流子迁移率，给出了精确测定其刃、螺位错密度的电学方法.研究表明，对于莫特相变材料（载流子浓度超过1018cm-3），以位错密度Ndis、刃螺位错密度比、刃位错周围浅施主电离能D1、螺位错周围浅施主电离能D2为拟合参数的载流子迁移率模型与实验曲线高度符合，拟合所得刃、螺位错密度与X射线衍射法或化学腐蚀方法的测试结果也基本一致.实验结果表明，莫特相变材料虽然载流子浓度高、霍尔迁移率低，但其位错密度却并不一定高过载流子浓度低、霍尔迁移率高的材料，应变也无明显差异，因此，莫特相变与刃、螺位错密度及两类位置最浅的施主均无关系，可能是位置较深的施主或其他缺陷所致，需要比一般杂质带高得多的载流子浓度.该方法适合霍尔迁移率在0 K附近不为零，霍尔迁移率曲线峰位300 K左右及以上的各种生长工艺、各种厚度、各种质量层次的薄膜材料，能够对迁移率曲线高度拟合，迅速给出莫特相变材料的相关精确参数.

关键词:

Abstract

An analytical model for electron mobility in a class of wurtzite n-GaN, whose carrier concentration is over 1018 cm-3 (Mott's critical limit), is developed. With the dislocation density and two donor levels serving as the important parameters, the proposed model can accurately predict the electron mobility as a function of temperature. The edge and screw dislocation densities in two samples, which are respectively grown on sapphire (001) by metal organic chemical vapor deposition and hydride vapor phase epitaxy, are determined by using this model which is discussed in detail. It is shown that the data-fitting of H-T characteristic curve is a highly suitable technique for accurately determining the edge and screw dislocation densities in n-GaN films. Quantitative analyses of donor concentration and donor activation energy indicate that the impurity band occurs when the carrier concentration is under 1017 cm-3, much lower than the critical carrier concentration of Mott transition (1018 cm-3). Such a behavior can also be confirmed by the results from solving the Boltzmann transport equation by using the Rode iterative method. Another anomaly is that the dislocation density in Mott transition material perhaps is lower than that of material with carrier concentration under 1018 cm-3. This fact indicates that the cause of Mott transition should not be the shallow donor impurities around dislocation lines, but perhaps the deeper donor impurities or other defects. In the theoretical model calculation, two transition characteristics together with the donor distribution and its energy equilibrium are taken into account. Based both on the Mott transition and the H-like electron state model, the relaxation energies for the shallow-donor defects along the screw and edge dislocation lines are calculated by using an electrical ensemble average method. Besides, an assumption that should be made is that there are 6 shallow-donor defect lines around one dislocation line. The research results show that the Hall mobility should be taken as the live degree of the ionizing energy for the shallow-donor defects along the dislocation line. The experimental results indicate that our calculation function can be best fit by the experimental curve, with the values of dislocation density being between our model and others determined by X-ray diffraction or by chemical etching method, which are all in good agreement with each other. The method reported can be applied to the wurtzite n-GaN films grown by various preparation technologies under any condition, with the peak-mobility temperature about or over 300 K, whose Hall mobility near 0 K perhaps is over 10 cm2/(Vs) and even 100 cm2/(Vs).

Keywords:

作者及机构信息

1.
南昌大学科学技术学院, 南昌 330029;

2.
南昌大学材料科学与工程学院, 南昌 330031;

3.
上饶职业技术学院机械工程系, 上饶 334100;

4.
核技术应用教育部工程研究中心(东华理工大学), 南昌 330013;

5.
南昌大学现代教育技术中心, 南昌 330031

通信作者: 何菊生, Hejusheng_2004@sohu.com

基金项目: 江西省自然科学基金（批准号：20151BAB207066）和南昌大学科学技术学院自然科学基金（批准号：2012-ZR-06）资助的课题.

Authors and contacts

1.
School of Science and Technology, Nanchang University, Nanchang 330029, China;

2.
School of Material Science and Engineering, Nanchang University, Nanchang 330031, China;

3.
Department of Mechanical Engineering, Shangrao Vocational and Technical College, Shangrao 334100, China;

4.
Engineering Research Center of Nuclear Technology Application(East China Institute of Technology), Ministry of Education, Nanchang 330013, China;

5.
Modern Education Technology Center of Nanchang University, Nanchang 330031, China

Corresponding author: He Ju-Sheng, Hejusheng_2004@sohu.com

Funds: Project supported by the Natural Science Foundation of Jiangxi Province, China (Grant No. 20151BAB207066) and the Natural Science Foundation of College of Science and Technology of Nanchang University, China (Grant No. 2012-ZR-06).

参考文献

[1]	Zhang Y, Xie Z L, Wang J, Tao T, Zhang R, Liu B, Chen P, Han P, Shi Y, Zheng Y D 2013 Acta Phys. Sin. 62 056101 (in Chinese) [张韵, 谢自力, 王健, 陶涛, 张荣, 刘斌, 陈鹏, 韩平, 施毅, 郑有炓 2013 62 056101]
[2]	Qi W J, Zhang M, Pan S, Wang X L, Zhang J L, Jiang F Y 2016 Acta Phys. Sin. 65 077801 (in Chinese) [齐维靖, 张萌, 潘拴, 王小兰, 张建立, 江风益 2016 65 077801]
[3]	He J S, Zhang M, Pan H Q, Qi W J, Li P 2016 Acta Phys. Sin. 65 167201 (in Chinese) [何菊生, 张萌, 潘华清, 齐维靖, 李平 2016 65 167201]
[4]	Mavroidis C, Harris J J, Jackman R B, Harrison I, Ansell B J, Bougrioua Z, Moerman I 2002 J. Appl. Phys. 91 9835
[5]	James A F, Yeo Y K, Ryu M Y, Hengehold R L 2005 J. Electron. Mater. 34 1157
[6]	Osinnykh I V, Zhuravlev K S, Malin T V, Ber B Y, Kazantsev D Y 2014 Semiconductors 48 1134
[7]	Srikant V, Speck J S, Clarke D R 1997 J. Appl. Phys. 82 4286
[8]	Zhang Z, Zhang R, Xie Z L, Liu B, Xiu X Q, Jiang R L, Han P, Gu S L, Shi Y, Zheng Y D 2008 Sci. China Ser. G:-Phys. Mech. Astron. 51 1046
[9]	Ding Z B, Yao S D, Wang K, Cheng K 2006 Acta Phys. Sin. 55 2977 (in Chinese) [丁志博, 姚淑德, 王坤, 程凯 2006 55 2977]
[10]	Look D C, Sizelove J R 2001 Appl. Phys. Lett. 79 1133
[11]	Look D C, Sizelove J R, Keller S, Wu Y F, Mishra U K, DenBaas S P 1997 Solid State Commun. 102 297

施引文献

[1]	Zhang Y, Xie Z L, Wang J, Tao T, Zhang R, Liu B, Chen P, Han P, Shi Y, Zheng Y D 2013 Acta Phys. Sin. 62 056101 (in Chinese) [张韵, 谢自力, 王健, 陶涛, 张荣, 刘斌, 陈鹏, 韩平, 施毅, 郑有炓 2013 62 056101]
[2]	Qi W J, Zhang M, Pan S, Wang X L, Zhang J L, Jiang F Y 2016 Acta Phys. Sin. 65 077801 (in Chinese) [齐维靖, 张萌, 潘拴, 王小兰, 张建立, 江风益 2016 65 077801]
[3]	He J S, Zhang M, Pan H Q, Qi W J, Li P 2016 Acta Phys. Sin. 65 167201 (in Chinese) [何菊生, 张萌, 潘华清, 齐维靖, 李平 2016 65 167201]
[4]	Mavroidis C, Harris J J, Jackman R B, Harrison I, Ansell B J, Bougrioua Z, Moerman I 2002 J. Appl. Phys. 91 9835
[5]	James A F, Yeo Y K, Ryu M Y, Hengehold R L 2005 J. Electron. Mater. 34 1157
[6]	Osinnykh I V, Zhuravlev K S, Malin T V, Ber B Y, Kazantsev D Y 2014 Semiconductors 48 1134
[7]	Srikant V, Speck J S, Clarke D R 1997 J. Appl. Phys. 82 4286
[8]	Zhang Z, Zhang R, Xie Z L, Liu B, Xiu X Q, Jiang R L, Han P, Gu S L, Shi Y, Zheng Y D 2008 Sci. China Ser. G:-Phys. Mech. Astron. 51 1046
[9]	Ding Z B, Yao S D, Wang K, Cheng K 2006 Acta Phys. Sin. 55 2977 (in Chinese) [丁志博, 姚淑德, 王坤, 程凯 2006 55 2977]
[10]	Look D C, Sizelove J R 2001 Appl. Phys. Lett. 79 1133
[11]	Look D C, Sizelove J R, Keller S, Wu Y F, Mishra U K, DenBaas S P 1997 Solid State Commun. 102 297

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