兴奋剂
材料科学
氢
半导体
硅
杂质
光电子学
实现(概率)
电子顺磁共振
纳米技术
热传导
机制(生物学)
氢原子
密度泛函理论
宽禁带半导体
化学物理
电子
Atom(片上系统)
半导体器件
导带
功能(生物学)
混合功能
凝聚态物理
化学
工程物理
原子物理学
半导体材料
浅层供体
自由电子模型
作者
Akira Kiyoi,Yusuke Nishiya,Yuichiro Matsushita,T. Umeda
标识
DOI:10.1038/s43246-025-00955-4
摘要
Doping, a critical technology in semiconductor device fabrication, is conventionally realized using substitutional impurities as dopants. New ideas and breakthroughs can help realize wide-bandgap materials with unconventional dopants. In this study, we explored a novel n-type doping mechanism using the donor nature of hydrogen-related donors in silicon to address the limitations of conventional doping. Certain defects, such as interstitial-type defects, create defect levels near the conduction band edge, which function as “empty donor levels.” The association of hydrogen with these defects generates free electrons through the transfer of an electron from the hydrogen atom to this empty level. This synergistic approach of hydrogen and defects can be demonstrated reliably and controllably in state-of-the-art Si devices. The mechanism, revealed by density functional theoretical calculation and EPR experiments, potentially expands this approach to other materials, providing a novel method for device optimization such as the realization of low-resistivity contacts. Doing is a key approach for controlling the properties of semiconductors. Here, a new n-type doping mechanism is reported for silicon, involving hydrogen association with interstitial-type defects to generate free electrons.
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