Suppression of Enhanced Magnesium Diffusion During High‐Pressure Annealing of Implanted GaN

physica status solidi (a) Pub Date : 2024-05-19 DOI:10.1002/pssa.202400080

A. Jacobs, B. Feigelson, J. S. Lundh, J. Spencer, J. A. Freitas, B. Gunning, R. J. Kaplar, Yuhao Zhang, M. Tadjer, K. Hobart, T. Anderson

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Abstract

Activation of ion‐implanted p‐type dopants in gallium nitride has demonstrated great progress utilizing high pressures to enable novel and traditional device architectures; however, such conditions consistently exhibit anomalously enhanced diffusion up to several microns in very short periods of time for device relevant concentrations. Here, this diffusion is shown to be modulated by unintentional hydrogen content within the anneal ambient and thus controllable by inclusion of a high‐temperature hydrogen getter. Furthermore, diffusion is also shown to be greatly suppressed using co‐implanted oxygen at low concentrations while simultaneously maintaining characteristics of p‐type material in photoluminescence. Subsequently, after annealing at 1300 °C for 30 min in 3.8 kbar of nitrogen pressure, the magnesium concentration in the diffusion tail is suppressed by 28% at 1–1.5 μm in depth using a hydrogen getter alone, which reduces hydrogen uptake by 45% and fully suppressed at >1 μm in depth using co‐implantation alone and further reduced with concurrent use of a hydrogen getter. Co‐implantation alone reduces the in‐diffused magnesium dose by 60% compared to reference samples.

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抑制植入式氮化镓高压退火过程中的镁扩散增强效应

利用高压活化氮化镓中的离子注入 p 型掺杂剂在实现新型和传统器件架构方面取得了巨大进步；然而，在这种条件下，器件相关浓度在很短时间内的扩散持续异常增强，可达数微米。这里的研究表明，这种扩散受退火环境中无意氢含量的调节，因此可通过加入高温氢获取器来控制。此外，研究还表明，在低浓度下使用共同植入的氧气可以极大地抑制扩散，同时在光致发光中保持 p 型材料的特性。随后，在 3.8 千巴的氮气压力下于 1300 °C 退火 30 分钟后，在 1-1.5 μm 的深度内，仅使用氢获取剂可将扩散尾部的镁浓度抑制 28%，从而将氢吸收率降低 45%，在 >1 μm 的深度内，仅使用共植入可将氢吸收率完全抑制，而同时使用氢获取剂可进一步降低镁浓度。与参考样本相比，单独共同植入可将镁的内扩散剂量减少 60%。

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physica status solidi (a)

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