{"title":"氮化镓的缺陷选择性光刻:进展、应用与前景","authors":"J.L. Weyher , J.J. Kelly","doi":"10.1016/j.pcrysgrow.2024.100623","DOIUrl":null,"url":null,"abstract":"<div><p>Defect-selective etching methods are commonly used for a quick assessment of crystallographic and chemical inhomogeneities in various semiconductors, including nitrides. Because of the stability of GaN, \"extreme\" etchants such as molten bases and hot phosphoric/sulfuric acids are required for chemical etching. Photoetching provided an alternative and attractive path for room temperature etching of GaN. In this comprehensive review the introduction and subsequent modification of the photoetching method used for revealing defects and inhomogeneities in GaN are described in detail. The initial etchant, a KOH-based aqueous solution, was subsequently modified by addition of potassium peroxydisulphate (K<sub>2</sub>S<sub>2</sub>O<sub>8</sub>), and later trisodium phosphate (Na<sub>3</sub>PO<sub>4</sub>) was added. The mechanism of photoetching in these solutions is presented and the advantages of using two- and three-component solutions are considered. This mechanism is based on generation of charge carriers (electrons and holes) by illumination of GaN with supra-bandgap light and was named photo-electrochemical (PEC) method. A correlation has been established between the carrier concentration in n-type GaN and the photoetch rate. A model is outlined that allows interpretation of large differences in the photoetch rate of inhomogeneous samples. Numerous examples of defects revealed by photoetching of GaN bulk crystals and homo- or hetero-epitaxial layers are described. The corresponding models for the formation of etch features are discussed and the results are compared with those obtained from other structural methods used for analysis of novel defects found in ammonothermally grown GaN crystals. The range of defects revealed by photoetching in GaN includes dislocations, inversion domains, nano-pipes, nano-scale and extended inhomogeneities. The importance of using photoetching for analysis of potentially new types of defect in recently grown ammonothermally GaN bulk crystals is emphasized. Future prospects of the PEC method for analysis of defects are considered.</p></div>","PeriodicalId":409,"journal":{"name":"Progress in Crystal Growth and Characterization of Materials","volume":"70 2","pages":"Article 100623"},"PeriodicalIF":4.5000,"publicationDate":"2024-05-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Defect selective photoetching of GaN: Progress, applications and prospects\",\"authors\":\"J.L. Weyher , J.J. 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The mechanism of photoetching in these solutions is presented and the advantages of using two- and three-component solutions are considered. This mechanism is based on generation of charge carriers (electrons and holes) by illumination of GaN with supra-bandgap light and was named photo-electrochemical (PEC) method. A correlation has been established between the carrier concentration in n-type GaN and the photoetch rate. A model is outlined that allows interpretation of large differences in the photoetch rate of inhomogeneous samples. Numerous examples of defects revealed by photoetching of GaN bulk crystals and homo- or hetero-epitaxial layers are described. The corresponding models for the formation of etch features are discussed and the results are compared with those obtained from other structural methods used for analysis of novel defects found in ammonothermally grown GaN crystals. The range of defects revealed by photoetching in GaN includes dislocations, inversion domains, nano-pipes, nano-scale and extended inhomogeneities. The importance of using photoetching for analysis of potentially new types of defect in recently grown ammonothermally GaN bulk crystals is emphasized. 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引用次数: 0
摘要
缺陷选择性蚀刻方法通常用于快速评估包括氮化物在内的各种半导体的晶体学和化学不均匀性。由于氮化镓的稳定性,化学蚀刻需要使用 "极端 "蚀刻剂,如熔融碱和热磷酸/硫酸。光蚀刻为氮化镓的室温蚀刻提供了另一条极具吸引力的途径。本综述详细介绍了用于揭示氮化镓缺陷和不均匀性的光蚀刻方法的引入和后续修改。最初的蚀刻剂是一种基于 KOH 的水溶液,后来通过添加过氧化二硫酸钾(K2S2O8)和磷酸三钠(Na3PO4)进行了改进。介绍了在这些溶液中进行光蚀刻的机理,并考虑了使用双组分和三组分溶液的优势。这种机理基于用超带隙光照射氮化镓产生电荷载流子(电子和空穴),被命名为光-电化学(PEC)方法。n 型氮化镓中的载流子浓度与光蚀刻速率之间建立了相关性。概述的模型可以解释不均匀样品光蚀刻率的巨大差异。描述了大量通过光蚀刻 GaN 块状晶体和同外延层或异外延层而发现的缺陷实例。讨论了蚀刻特征形成的相应模型,并将结果与用于分析氨热法生长的氮化镓晶体中发现的新缺陷的其他结构方法得出的结果进行了比较。光刻法在氮化镓中发现的缺陷范围包括位错、反转域、纳米管道、纳米级和扩展不均匀性。利用光蚀刻分析最近生长的氨热法氮化镓块状晶体中潜在的新型缺陷的重要性得到了强调。研究还考虑了光蚀刻法分析缺陷的未来前景。
Defect selective photoetching of GaN: Progress, applications and prospects
Defect-selective etching methods are commonly used for a quick assessment of crystallographic and chemical inhomogeneities in various semiconductors, including nitrides. Because of the stability of GaN, "extreme" etchants such as molten bases and hot phosphoric/sulfuric acids are required for chemical etching. Photoetching provided an alternative and attractive path for room temperature etching of GaN. In this comprehensive review the introduction and subsequent modification of the photoetching method used for revealing defects and inhomogeneities in GaN are described in detail. The initial etchant, a KOH-based aqueous solution, was subsequently modified by addition of potassium peroxydisulphate (K2S2O8), and later trisodium phosphate (Na3PO4) was added. The mechanism of photoetching in these solutions is presented and the advantages of using two- and three-component solutions are considered. This mechanism is based on generation of charge carriers (electrons and holes) by illumination of GaN with supra-bandgap light and was named photo-electrochemical (PEC) method. A correlation has been established between the carrier concentration in n-type GaN and the photoetch rate. A model is outlined that allows interpretation of large differences in the photoetch rate of inhomogeneous samples. Numerous examples of defects revealed by photoetching of GaN bulk crystals and homo- or hetero-epitaxial layers are described. The corresponding models for the formation of etch features are discussed and the results are compared with those obtained from other structural methods used for analysis of novel defects found in ammonothermally grown GaN crystals. The range of defects revealed by photoetching in GaN includes dislocations, inversion domains, nano-pipes, nano-scale and extended inhomogeneities. The importance of using photoetching for analysis of potentially new types of defect in recently grown ammonothermally GaN bulk crystals is emphasized. Future prospects of the PEC method for analysis of defects are considered.
期刊介绍:
Materials especially crystalline materials provide the foundation of our modern technologically driven world. The domination of materials is achieved through detailed scientific research.
Advances in the techniques of growing and assessing ever more perfect crystals of a wide range of materials lie at the roots of much of today''s advanced technology. The evolution and development of crystalline materials involves research by dedicated scientists in academia as well as industry involving a broad field of disciplines including biology, chemistry, physics, material sciences and engineering. Crucially important applications in information technology, photonics, energy storage and harvesting, environmental protection, medicine and food production require a deep understanding of and control of crystal growth. This can involve suitable growth methods and material characterization from the bulk down to the nano-scale.
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