Silicon ultrafast recovery diode with leakage current reduced via the combined lifetime process of gold diffusion and electron-beam irradiation

IF 1.9 4区工程技术 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC

Semiconductor Science and Technology Pub Date : 2023-12-12 DOI:10.1088/1361-6641/ad14ec

Hideto Onishi, Hajime Shirai

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Abstract

We investigated the reduction in the reverse-biased leakage current of Si ultrafast recovery diodes via a combined lifetime process involving Au diffusion and bulk electron-beam irradiation. The leakage current of the combined-processed diode was significantly reduced to less than one-third of that of the diode processed solely with Au diffusion, maintaining a similar switching time of 32 ns. This reduction was not achievable with the sole use of electron-beam irradiation. Deep-level transient spectroscopy revealed that the reduction in the leakage current was due to the coexistence of the deep trap level of Au (Ec-0.51 eV) and the shallow trap level of the defects (Ec-0.39 eV) generated via electron-beam irradiation as lifetime killers. By combining the deep and shallow trap levels, the lifetime of the carriers generated in the depletion layer of the reverse-biased p-n junction becomes long and consequently, the leakage current is reduced. By maintaining the trap density ratio of defects to diffused Au above 0.28, the leakage current was reduced to less than one-third of that in the solely Au-diffused diode, while maintaining a similar switching time.

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通过金扩散和电子束辐照联合寿命过程降低漏电流的硅超快恢复二极管

我们研究了通过金扩散和体电子束辐照的组合寿命工艺来降低硅超高速恢复二极管的反向偏置漏电流。在保持类似的 32 ns 开关时间的情况下，组合工艺二极管的漏电流显著降低，不到单纯金扩散工艺二极管的三分之一。仅使用电子束辐照是无法实现这种降低的。深阱瞬态光谱显示，漏电流的降低是由于电子束辐照产生的金深阱电平（Ec-0.51 eV）和缺陷浅阱电平（Ec-0.39 eV）作为寿命杀手同时存在。通过结合深阱和浅阱电平，在反向偏置 p-n 结的耗尽层中产生的载流子的寿命变长，从而降低了漏电流。通过将缺陷与扩散金的陷阱密度比保持在 0.28 以上，漏电流降低到了纯金扩散二极管的三分之一以下，同时保持了相似的开关时间。

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来源期刊

Semiconductor Science and Technology 工程技术-材料科学：综合

CiteScore

4.30

自引率

5.30%

发文量

216

审稿时长

2.4 months

期刊介绍： Devoted to semiconductor research, Semiconductor Science and Technology''s multidisciplinary approach reflects the far-reaching nature of this topic. The scope of the journal covers fundamental and applied experimental and theoretical studies of the properties of non-organic, organic and oxide semiconductors, their interfaces and devices, including: fundamental properties materials and nanostructures devices and applications fabrication and processing new analytical techniques simulation emerging fields: materials and devices for quantum technologies hybrid structures and devices 2D and topological materials metamaterials semiconductors for energy flexible electronics.