HBT on LEO GaN

58th DRC. Device Research Conference. Conference Digest (Cat. No.00TH8526) Pub Date : 2000-06-19 DOI:10.1109/DRC.2000.877101

L. McCarthy, Y. Smorchkova, P. Fini, H. Xing, M. Rodwell, J. Speck, S. Denbaars, U. Mishra

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引用次数: 2

Abstract

Dramatic progress in GaN electronics has led to increased interest in bipolar transistors. Although there have been reports of GaN bipolars from several groups, the development of the GaN bipolar transistor is still in its fundamental stages. In the case of GaN, the usual correlation between common base, Gummel, and common emitter characteristics does not exist due to significant collector-emitter leakage, leaving only the common emitter characteristic as a reliable measure of DC device performance. We identify the source of this leakage as threading dislocations and clarify the effect of this leakage on the transistor DC characteristics. Furthermore, we conclude from various growth structures and methods of device fabrication that the electron lifetime in the neutral base is currently the limiting factor in GaN NPN transistor performance. Typical GaN material has high threading dislocation densities, 10/sup 7/-10/sup 9/ cm/sup -2/, due to lattice mismatch with the substrate, typically sapphire or SiC. To study the effects of threading dislocations on GaN bipolar transistors, we have fabricated devices on material grown using the lateral epitaxial overgrowth technique, LEO. To the authors' knowledge, this is the first demonstration of GaN bipolar transistors grown on nondislocated material. The LEO substrate allows us to compare devices grown on material with a negligible dislocation density with those grown on a standard template.

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氮化镓电子学的巨大进步增加了人们对双极晶体管的兴趣。虽然已经有几个小组报道了氮化镓双极晶体管，但氮化镓双极晶体管的发展仍处于基础阶段。在GaN的情况下，由于显著的集电极-发射极泄漏，通常的共基极、Gummel和共发射极特性之间的相关性不存在，只留下共发射极特性作为直流器件性能的可靠度量。我们确定这种泄漏的来源是螺纹错位，并澄清这种泄漏对晶体管直流特性的影响。此外，我们从各种生长结构和器件制造方法中得出结论，中性基极中的电子寿命目前是GaN NPN晶体管性能的限制因素。由于晶格与衬底(通常是蓝宝石或SiC)不匹配，典型的GaN材料具有高的螺纹位错密度，为10/sup 7/-10/sup 9/ cm/sup -2/。为了研究螺纹位错对GaN双极晶体管的影响，我们在使用横向外延过度生长技术(LEO)生长的材料上制造了器件。据作者所知，这是第一次在非位错材料上生长GaN双极晶体管。LEO衬底允许我们比较在具有可忽略的位错密度的材料上生长的器件与在标准模板上生长的器件。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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58th DRC. Device Research Conference. Conference Digest (Cat. No.00TH8526)

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