Enhancing two-dimensional growth of high-temperature AlN buffer to improve the quality of GaN on Si grown by ex situ two-step method

IF 1.7 4区材料科学 Q3 CRYSTALLOGRAPHY Journal of Crystal Growth Pub Date : 2024-10-20 DOI:10.1016/j.jcrysgro.2024.127958

Haiyan Wang , Zeqi Lin , Binhao Qin , Yupeng Zhang

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Abstract

GaN epitaxial films were grown on Si substrates by ex situ two-step method combining the technologies of pulsed laser deposition (PLD) and metal organic chemical vapor deposition (MOCVD). The N/Al ratio of high-temperature AlN (HT-AlN) buffer layer was optimized, and its influence on the HT-AlN growth mode as well as the quality of GaN epitaxial films was investigated. When the N/Al ratio was 500, the two-dimensional growth of HT-AlN was greatly enhanced, and it obtained a coalesced and smooth surface with the minimum RMS surface roughness as 1.63 nm. The as-grown GaN epitaxial film had the best crystalline quality with the minimum full-width at half maximums of GaN(0002) and GaN(10

\bar{1}

2) as 0.14° and 0.22°, respectively. Owing to the high energy of PLD, the ex situ low-temperature AlN template had an abrupt Si/AlN interface and flat surface, which was of significance to improve the quality of HT-AlN buffer and GaN film.

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增强高温氮化铝缓冲区的二维生长，以提高通过原位两步法在硅上生长的氮化镓的质量

结合脉冲激光沉积（PLD）和金属有机化学气相沉积（MOCVD）技术，采用原位两步法在硅衬底上生长了氮化镓外延薄膜。对高温 AlN（HT-AlN）缓冲层的 N/Al 比率进行了优化，并研究了其对 HT-AlN 生长模式和 GaN 外延薄膜质量的影响。当 N/Al 比为 500 时，HT-AlN 的二维生长能力大大增强，获得了凝聚光滑的表面，表面粗糙度均方根最小值为 1.63 nm。生长后的 GaN 外延膜具有最佳的结晶质量，GaN(0002) 和 GaN(10 1¯ 2) 的半最大全宽分别为 0.14° 和 0.22°。由于 PLD 的高能量，原位低温 AlN 模板具有突兀的 Si/AlN 界面和平坦的表面，这对提高 HT-AlN 缓冲区和 GaN 薄膜的质量具有重要意义。

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来源期刊

Journal of Crystal Growth 化学-晶体学

CiteScore

3.60

自引率

11.10%

发文量

373

审稿时长

65 days

期刊介绍： The journal offers a common reference and publication source for workers engaged in research on the experimental and theoretical aspects of crystal growth and its applications, e.g. in devices. Experimental and theoretical contributions are published in the following fields: theory of nucleation and growth, molecular kinetics and transport phenomena, crystallization in viscous media such as polymers and glasses; crystal growth of metals, minerals, semiconductors, superconductors, magnetics, inorganic, organic and biological substances in bulk or as thin films; molecular beam epitaxy, chemical vapor deposition, growth of III-V and II-VI and other semiconductors; characterization of single crystals by physical and chemical methods; apparatus, instrumentation and techniques for crystal growth, and purification methods; multilayer heterostructures and their characterisation with an emphasis on crystal growth and epitaxial aspects of electronic materials. A special feature of the journal is the periodic inclusion of proceedings of symposia and conferences on relevant aspects of crystal growth.