基于VIA族和IB族杂质深能级的硅亚带隙光谱响应机理研究

项目名称： 基于VIA族和IB族杂质深能级的硅亚带隙光谱响应机理研究

项目编号： No.61504139

项目类型： 青年科学基金项目

立项/批准年度： 2016

项目学科： 无线电电子学、电信技术

项目作者： 胡少旭

作者单位： 中国科学院半导体研究所

项目金额： 20万元

中文摘要： 硅亚带隙光谱响应在集成光通信与夜视成像中具有重要的应用价值。研究发现，超快激光非平衡掺杂VIA族和IB族杂质，可将硅的光谱响应波长拓宽至2200 nm。但是，宽光谱响应背后的物理机制，至今仍处于猜测推究阶段，国际上尚无科学依据予以阐释。亚带隙光谱响应对应低能光子的吸收与光电转换。而杂质深能级与低能光子在硅能带中的激发跃迁紧密关联。基于此，该课题拟在非平衡离子注入掺杂下，借助深能级瞬态谱测试、光电流激活能测试等技术，深入剖析超快激光对VIA族和IB族深能级杂质的替位、激活以及对其深能级特性的物理修正作用。通过研究杂质深能级对光生载流子的激发复合过程，最终揭示VIA族和IB族杂质深能级拓宽硅近红外光谱响应的物理根源，并建立纯物理的亚带隙光电响应模型，为新型硅光电子器件的研发提供理论与技术指导。

中文关键词： 带间跃迁；载流子输运；光电导；深能级；VIA；与；IB；族杂质

英文摘要： Silicon sub-bandgap spectral response has significant applications in integrated optical communications and night vision technology. It is found that ultrafast laser hyperdoping of VIA and IB group impurities into silicon can extend silicon response wavelength to 2200 nm. But, the physical mechanism behind the broad spectral response is still ambiguous up to now, and no valid evidence can explain this unique optoelectronic property. Evidently, sub-bandgap spectral response is caused by the absorption of low energy-photons and optical-to-electric conversion. However, the optical excitation and transition of low energy-photons in silicon bandgap is closely related to the impurity-introduced deep levels. So, in this item, the influence of ultrafast laser irradiation on the substitution, activation of VIA and IB group impurities in silicon, and on the properties of impurity-introduced deep levels will be investigated comprehensively by a combination of deep level transient spectroscopy method with photocurrent activation test technique under non equilibrium ion implantation doping. At last, the effects of impurity-introduced deep levels on the generation and recombination of photo carriers will be studied to illuminate the physical source of silicon near infrared spectral response broadened by the VIA and IB group impurities. Finally, the sub-bandgap spectral response model will be built based on theoretical physics to provide theoretical and technical guidance for the fabrication of novel silicon optoelectronic devices.

英文关键词： interband transition;carrier transport;photoconductivity;deep level;VIA and IB group impurity