A. Reyes, S. El-Ghazaly, S. Dorn, M. Dydyk, D. Schroder, H. Patterson
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引用次数: 41
摘要
硅作为系统衬底材料具有成本低、技术成熟等优点。然而,与半绝缘的砷化镓或石英相比,硅尚未被证明是一种良好的微波衬底。本文的目的是通过实验对比研究来评估高电阻硅作为低成本低损耗微波衬底的潜力。测试了在硅、砷化镓和石英衬底上制备的共面波导,并比较了它们的特性。在不同的衬底上制作了微波螺旋电感器和弯曲线,并对其性能进行了分析。结果表明,在高电阻率(3 k ~ 7 k /spl ω /-cm)硅衬底上实现的共面传输线损耗与在覆盖绝缘体的砷化镓衬底上实现的共面传输线损耗相当。此外,在高电阻硅衬底上测量的微波感应结构的空载Q值与在砷化镓和石英上测量的相同结构的空载Q值相当。用微波和半导体物理理论对测量结果进行了解释。本文论证了高电阻率硅可以用作微波衬底。
Silicon has many advantages as a system substrate material including low cost and a mature technology. However, Si has not been demonstrated as a good microwave substrate compared to semi-insulating GaAs or quartz. The aim of this paper is to evaluate the potential of using high-resistivity silicon as a low-cost low-loss microwave substrate through an experimental comparative study. Coplanar waveguides fabricated on Si, GaAs and quartz substrates are tested and their characteristics are compared. Microwave spiral inductors and meander lines are also fabricated on various substrates, and their performance is also analyzed. The results demonstrate that the losses of a coplanar transmission line (CPW) realized on high-resistivity (3 k to 7 k /spl Omega/-cm) silicon substrates are comparable to the losses of a CPW realized on a GaAs substrate covered with insulator. Furthermore, measured unloaded Q's of microwave inductive structures on high-resistivity silicon substrates are comparable to the measured unloaded Q's of the same structures on GaAs and on quartz. The measured results are explained using both microwave and semiconductor physics theory. This paper demonstrates that high-resistivity Si can be used as a microwave substrate.
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