β-Ga2O3离子注入:物理与技术

A. Nikolskaya, E. Okulich, D. Korolev, A. Stepanov, D. Nikolichev, A. Mikhaylov, D. Tetelbaum, A. Almaev, C. A. Bolzan, A. Buaczik, R. Giulian, P. L. Grande, Ashok Kumar, Mahesh Kumar, D. Gogova
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引用次数: 36

摘要

氧化镓,特别是其热力学稳定的β-Ga2O3相,由于其独特的性能,是当今研究和技术中最令人兴奋的材料之一。非常高的击穿电场和只有钻石能与之匹敌的性能数字,对下一代“绿色”电子产品具有巨大的潜力,可以有效地分配、使用和转换电能。离子注入是用于这些领域的传统技术方法,其众所周知的优点可以极大地促进ga2o3基材料和器件的物理和技术的快速发展。本文综述了离子注入β-Ga2O3的研究现状。重点关注了离子辐照损伤的实验研究结果和离子注入后Ga2O3层的性能。简要介绍了杂质和缺陷参数的从头算理论计算结果,并重点介绍了用于研究注入氧化镓层的一些分析方法的物理原理。介绍了离子注入在ga2o3基器件(如金属氧化物场效应晶体管、肖特基势垒二极管和太阳盲紫外探测器)开发中的应用,并系统地分析了其特性的实现值。最后,讨论了在这一科学技术领域需要克服的最重要的挑战。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Ion implantation in β-Ga2O3: Physics and technology
Gallium oxide, and in particular its thermodynamically stable β-Ga2O3 phase, is within the most exciting materials in research and technology nowadays due to its unique properties. The very high breakdown electric field and the figure of merit rivaled only by diamond have tremendous potential for the next generation “green” electronics enabling efficient distribution, use, and conversion of electrical energy. Ion implantation is a traditional technological method used in these fields, and its well-known advantages can contribute greatly to the rapid development of physics and technology of Ga2O3-based materials and devices. Here, the status of ion implantation in β-Ga2O3 nowadays is reviewed. Attention is mainly paid to the results of experimental study of damage under ion irradiation and the properties of Ga2O3 layers doped by ion implantation. The results of ab initio theoretical calculations of the impurities and defect parameters are briefly presented, and the physical principles of a number of analytical methods used to study implanted gallium oxide layers are highlighted. The use of ion implantation in the development of Ga2O3-based devices, such as metal oxide field-effect transistors, Schottky barrier diodes, and solar-blind UV detectors, is described together with systematical analysis of the achieved values of their characteristics. Finally, the most important challenges to be overcome in this field of science and technology are discussed.
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