低噪声、高电子迁移率晶体管

1984 IEEE MTT-S International Microwave Symposium Digest Pub Date : 1984-05-01 DOI:10.1109/MWSYM.1984.1131703

J. Berenz, K. Nakano, K. Weller

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引用次数: 44

摘要

采用直写电子束光刻技术制备了用于低噪声EHF放大器的亚半微米栅长高电子迁移率晶体管(HEMT)。通过分子束外延生长出调制掺杂外延结构，室温为8,000 cm/sup 2//V-sec，液氮的霍尔迁移率为77600 cm/sup 2//V-sec，为10/sup 12/电子/cm/sup 2/。在通过n+ GaAs接触层蚀刻的凹槽中定义了窄至0.28微米的栅极长度。0.4微米栅长耗尽模式器件的直流跨导超过260 mS/mm。对于栅极长度为0.37微米的器件，在室温下进行的噪声系数和相关增益的初步测量得出，在34 GHz频率下噪声系数为2.7 dB，相关增益为5.9 dB。还制备了具有240 mS/mm直流跨导的增强模式器件。这些器件在0.35微米栅极长度的18 GHz下产生1.5 dB噪声系数和10.5 dB相关增益。这些结果可与目前报道的最佳四分之一微米栅极长度GaAs MESFET噪声数据相媲美。

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Low Noise High Electron Mobility Transistors

Sub-half-micron gate length High Electron Mobility Transistors [HEMT) were fabricated by direct-write electron beam lithography for low noise EHF amplifiers. Modulation-doped epitaxial structures were grown by molecular beam epitaxy having 8,000 cm /sup 2//V-sec room temperature and 77,600 cm/sup 2//V-sec liquid nitrogen Hall mobility for 10/sup 12/ electrons/cm/sup 2/. Gate lengths as narrow as 0.28 micron were defined in a recess etched through the n+ GaAs contact layer. The dc transconductance of 0.4 micron gate length depletion mode devices exceeded 260 mS/mm. Preliminary measurement of noise figure and associated gain made at room temperature yielded 2.7 dB noise figure and 5.9 dB associated gain at 34 GHz for devices having 0.37 micron gate length. Enhancement mode devices were also fabricated having 240 mS/mm dc transconductance. These devices yielded 1.5 dB noise figure and 10.5 dB associated gain at 18 GHz for 0.35 micron gate length. These results are comparable to the best quarter-micron gate length GaAs MESFET noise figures yet reported.

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1984 IEEE MTT-S International Microwave Symposium Digest

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