下一代2.5 THz SLCFET器件的良率和缩放改进，以支持超宽带DC-110GHz开关mmic

2021 IEEE BiCMOS and Compound Semiconductor Integrated Circuits and Technology Symposium (BCICTS) Pub Date : 2021-12-05 DOI:10.1109/BCICTS50416.2021.9682468

J. Mlack, Nick Edwards, Brian Novak, Annaliese Drechsler, Jordan Merkel, T. Vasen, D. Hannan, P. Brabant, I. Wathuthanthri, J. Parke, S. Wanis, R. Howell, Ken A. Nagamatsu

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引用次数: 2

摘要

本文报道了对超晶格场效应晶体管(SLCFET) 10通道器件工艺的改进，以实现超宽带DC-110GHz单极双掷和三掷(SPDT/SP3T) mmic的制造。10通道SLCFET器件提供更高的性能，但更难以制造。通过器件接触垫的平面化，改进了栅电极的制造，从而使器件的直流成品率提高了50%以上。此外，平整化使器件源极/漏极间距达到基准器件的64%，同时保持大于50%的直流良率。源极/漏极间距的减小降低了导通电阻，同时对关断电容的影响最小，从而实现更高的开关性能因数Fco >3THz。改进的FET设计改善了宽带SPDT和SP3T mmic的插入损耗，但隔离度没有变化。与其他传统技术相比，这些超宽带mmic具有更好的插入损耗和带宽。

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Yield and Scaling Improvements in Next-Generation 2.5 THz SLCFET Devices to Enable Ultra-wideband DC-110GHz Switch MMICs

This paper reports improvements in the Superlattice Castellated Field Effect Transistor (SLCFET) 10-channel device process to enable fabrication of ultra-wideband DC-110GHz Single Pole Double and Triple Throw (SPDT/SP3T) MMICs. The 10-channel SLCFET device offers higher performance, but is more difficult to fabricate. Through planarization of the device contact pads, the fabrication of the gate electrode is improved, thereby improving DC yield for the devices by more than 50%. Additionally, the planarization has enabled the scaling of the device source/drain spacing to 64% of baseline devices while maintaining a greater than 50% DC yield. The decrease in the source/drain spacing reduces on-resistance while minimally impacting the off-capacitance, leading to a higher achievable switch Figure of Merit Fco >3THz. The improved FET designs demonstrated improved insertion loss in the wideband SPDT and SP3T MMICs while showing no change in isolation. These ultra-wideband MMICs offer better insertion loss and bandwidth than is possible from other conventional technologies.

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2021 IEEE BiCMOS and Compound Semiconductor Integrated Circuits and Technology Symposium (BCICTS)

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