Molecular beam epitaxy as a growth technique for achieving free-standing zinc-blende GaN and wurtzite AlxGa1-xN

IF 4.5 2区 材料科学 Q1 CRYSTALLOGRAPHY
S.V. Novikov, A.J. Kent, C.T. Foxon
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引用次数: 18

Abstract

Currently there is a high level of interest in the development of ultraviolet (UV) light sources for solid-state lighting, optical sensors, surface decontamination and water purification. III-V semiconductor UV LEDs are now successfully manufactured using the AlGaN material system; however, their efficiency is still low. The majority of UV LEDs require AlxGa1-xN layers with compositions in the mid-range between AlN and GaN. Because there is a significant difference in the lattice parameters of GaN and AlN, AlxGa1-xN substrates would be preferable to those of either GaN or AlN for many ultraviolet device applications. However, the growth of AlxGa1-xN bulk crystals by any standard bulk growth techniques has not been developed so far.

There are very strong electric polarization fields inside the wurtzite (hexagonal) group III-nitride structures. The charge separation within quantum wells leads to a significant reduction in the efficiency of optoelectronic device structures. Therefore, the growth of non-polar and semi-polar group III-nitride structures has been the subject of considerable interest recently. A direct way to eliminate polarization effects is to use non-polar (001) zinc-blende (cubic) III-nitride layers. However, attempts to grow zinc-blende GaN bulk crystals by any standard bulk growth techniques were not successful.

Molecular beam epitaxy (MBE) is normally regarded as an epitaxial technique for the growth of very thin layers with monolayer control of their thickness. In this study we have used plasma-assisted molecular beam epitaxy (PA-MBE) and have produced for the first time free-standing layers of zinc-blende GaN up to 100 μm in thickness and up to 3-inch in diameter. We have shown that our newly developed PA-MBE process for the growth of zinc-blende GaN layers can also be used to achieve free-standing wurtzite AlxGa1-xN wafers. Zinc-blende and wurtzite AlxGa1-xN polytypes can be grown on different orientations of GaAs substrates - (001) and (111)B respectively. We have subsequently removed the GaAs using a chemical etch in order to produce free-standing GaN and AlxGa1-xN wafers. At a thickness of ∼30 µm, free-standing GaN and AlxGa1-xN wafers can easily be handled without cracking. Therefore, free-standing GaN and AlxGa1-xN wafers with thicknesses in the 30–100 μm range may be used as substrates for further growth of GaN and AlxGa1-xN-based structures and devices.

We have compared different RF nitrogen plasma sources for the growth of thick nitride AlxGa1-xN films including a standard HD25 source from Oxford Applied Research and a novel high efficiency source from Riber. We have investigated a wide range of the growth rates from 0.2 to 3 µm/h. The use of highly efficient nitrogen RF plasma sources makes PA-MBE a potentially viable commercial process, since free-standing films can be achieved in a single day.

Our results have demonstrated that MBE may be competitive with the other group III-nitrides bulk growth techniques in several important areas including production of free-standing zinc-blende (cubic) (Al)GaN and of free-standing wurtzite (hexagonal) AlGaN.

分子束外延是制备独立锌-闪锌矿GaN和纤锌矿AlxGa1-xN的生长技术
目前,人们对开发用于固态照明、光学传感器、表面净化和水净化的紫外光源非常感兴趣。III-V型半导体UV led现已成功使用AlGaN材料系统制造;然而,它们的效率仍然很低。大多数UV led需要AlxGa1-xN层,其成分介于AlN和GaN之间的中间范围。由于GaN和AlN的晶格参数存在显著差异,因此在许多紫外器件应用中,AlxGa1-xN衬底将优于GaN或AlN衬底。然而,目前还没有任何标准的体生长技术来生长AlxGa1-xN体晶体。纤锌矿(六方)iii族氮化物结构内部存在很强的电极化场。量子阱中的电荷分离导致光电器件结构效率的显著降低。因此,非极性和半极性iii族氮化物结构的生长已成为近年来人们非常感兴趣的课题。消除极化效应的一种直接方法是使用非极性(001)锌-闪锌矿(立方)iii型氮化物层。然而,试图通过任何标准的体生长技术生长锌掺杂氮化镓体晶体都不成功。分子束外延(MBE)通常被认为是一种生长极薄层的外延技术,其厚度由单层控制。在这项研究中,我们使用了等离子体辅助分子束外延(PA-MBE),并首次生产出了厚度达100 μm、直径达3英寸的独立锌掺杂氮化镓层。我们已经证明,我们新开发的PA-MBE工艺用于生长锌掺杂氮化镓层,也可以用于获得独立的纤锌矿AlxGa1-xN晶圆。锌闪锌矿和纤锌矿AlxGa1-xN多型可以分别生长在GaAs衬底-(001)和(111)B的不同取向上。我们随后使用化学蚀刻去除GaAs,以生产独立的GaN和AlxGa1-xN晶圆。在~ 30µm的厚度下,独立的GaN和AlxGa1-xN晶圆可以很容易地处理而不会破裂。因此,厚度在30-100 μm范围内的独立GaN和AlxGa1-xN晶圆可以用作进一步生长GaN和AlxGa1-xN基结构和器件的衬底。我们比较了用于生长厚氮化AlxGa1-xN薄膜的不同射频氮等离子体源,包括来自牛津应用研究公司的标准HD25源和来自Riber的新型高效源。我们研究了从0.2到3µm/h的生长速率范围。高效氮射频等离子体源的使用使PA-MBE成为一种潜在可行的商业工艺,因为独立薄膜可以在一天内完成。我们的研究结果表明,MBE可能在几个重要领域与其他iii族氮化物体生长技术竞争,包括生产独立的锌-铀矿(立方)(Al)GaN和独立的纤锌矿(六方)AlGaN。
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来源期刊
Progress in Crystal Growth and Characterization of Materials
Progress in Crystal Growth and Characterization of Materials 工程技术-材料科学:表征与测试
CiteScore
8.80
自引率
2.00%
发文量
10
审稿时长
1 day
期刊介绍: Materials especially crystalline materials provide the foundation of our modern technologically driven world. The domination of materials is achieved through detailed scientific research. Advances in the techniques of growing and assessing ever more perfect crystals of a wide range of materials lie at the roots of much of today''s advanced technology. The evolution and development of crystalline materials involves research by dedicated scientists in academia as well as industry involving a broad field of disciplines including biology, chemistry, physics, material sciences and engineering. Crucially important applications in information technology, photonics, energy storage and harvesting, environmental protection, medicine and food production require a deep understanding of and control of crystal growth. This can involve suitable growth methods and material characterization from the bulk down to the nano-scale.
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