High‐Temperature Annealing of Si‐Doped AlGaN

physica status solidi (a) Pub Date : 2024-01-31 DOI:10.1002/pssa.202300897

N. Zainal, S. Hagedorn, C. Netzel, T. Kolbe, Markus Weyers

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Abstract

This study explores the impact of Si doping on the material properties of high‐temperature annealed (HTA) Al0.71Ga0.29N layers, which are grown on AlN/sapphire templates. The AlGaN layers are doped with Si by applying different IV/III ratios during epitaxial growth and compared to undoped Al0.71Ga0.29N. Before HTA, the threading dislocation density (TDD) for all samples is about 6.0 × 109 cm−2. After HTA, the Si‐doped AlGaN grown with the highest IV/III ratio of 3.6 × 104 shows the lowest TDD of 1.2 × 109 cm−2. Secondary ion mass spectrometry depth profiles reveal an accelerated Ga diffusion from the doped AlGaN into the AlN buffer layer compared to undoped AlGaN. This suggests that the Ga diffusion process is mediated by Si diffusion. Consequently, the Ga diffusion leads to a decrease in the Ga mole fraction of annealed Si‐doped AlGaN. Furthermore, strain relaxation is higher for the Si‐doped AlGaN than for the undoped AlGaN, before and after HTA. The results from this study suggest that Si doping can be a new promising approach in enhancing the quality of HTA‐AlGaN as a useful template for the growth of UV LED heterostructures.

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硅掺杂氮化铝的高温退火

本研究探讨了在氮化铝/蓝宝石模板上生长的高温退火（HTA）Al0.71Ga0.29N 层掺杂硅对其材料特性的影响。在外延生长过程中，通过采用不同的 IV/III 比率对 AlGaN 层进行硅掺杂，并与未掺杂的 Al0.71Ga0.29N 层进行比较。在 HTA 之前，所有样品的穿线位错密度（TDD）约为 6.0 × 109 cm-2。在 HTA 之后，以 3.6 × 104 的最高 IV/III 比率生长的掺硅 AlGaN 的 TDD 最低，为 1.2 × 109 cm-2。二次离子质谱深度剖面图显示，与未掺杂 AlGaN 相比，掺杂 AlGaN 中的镓加速扩散到 AlN 缓冲层中。这表明镓的扩散过程是由硅扩散介导的。因此，镓扩散导致退火硅掺杂 AlGaN 的镓摩尔分数下降。此外，在 HTA 前后，Si-掺杂 AlGaN 的应变松弛均高于未掺杂 AlGaN。这项研究的结果表明，掺杂硅可以成为提高 HTA-AlGaN 质量的一种新方法，而 HTA-AlGaN 是生长紫外 LED 异质结构的有用模板。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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physica status solidi (a)

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