S-parameter based device-level C-V measurement of p-i-n single-drift IMPATT diode for millimeter-wave applications

2016 IEEE MTT-S International Wireless Symposium (IWS) Pub Date : 2016-03-14 DOI:10.1109/IEEE-IWS.2016.7585419

Wogong Zhang, M. Oehme, K. Kostecki, K. Matthies, V. Stefani, Ashraful I. Raju, D. Noll, V. S. Senthil Srinivasan, R. Korner, E. Kasper, J. Schulze

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Abstract

Two different approaches of capacitance-voltage (C-V) measurement were applied to the fabricated single-drift (SD) impact-ionization avalanche transit-time (IMPATT) structures. From both the C-V results, the carrier concentrations of depleted space-charge-region (SCR) width characteristics were calculated. According to the epitaxial thickness and the doping concentration of the lightly n-doped layer, the approach applied to a 30 × 2 μm2 IMPATT device, which is based on small-signal S-parameter characterization (0.04-40 GHz), showed better agreement compared with the approach applied to a C-V structure (0.64 mm2) using the conventional low frequency (1 MHz) C-V instrument. Additionally, the E-band IMPATT operation of the 30 × 2 μm2 device has been well modelled with the capacitance value extracted from the S-parameter based C-V measurement. The good agreement between device modelling and measurement within frequency range 0.04-110 GHz shows the reliability of the small-signal S-parameter device-level C-V measurement for real mm-wave application scenarios.

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基于s参数的毫米波应用中p-i-n单漂移IMPATT二极管的器件级C-V测量

采用两种不同的电容电压(C-V)测量方法对制备的单漂移(SD)冲击电离雪崩传递时间(IMPATT)结构进行了测量。根据C-V结果，计算了耗尽空间电荷区(SCR)宽度特性的载流子浓度。根据外延厚度和轻n掺杂层的掺杂浓度，该方法应用于基于小信号s参数表征(0.04 ~ 40 GHz)的30 × 2 μm2 IMPATT器件，与使用传统低频(1 MHz) C-V仪器应用于C-V结构(0.64 mm2)的方法相比，具有更好的一致性。此外，利用基于s参数的C-V测量提取的电容值，很好地模拟了30 × 2 μm2器件的e波段IMPATT操作。在0.04 ~ 110 GHz频率范围内，器件建模与测量结果吻合良好，表明了小信号s参数器件级C-V测量在实际毫米波应用场景下的可靠性。

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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2016 IEEE MTT-S International Wireless Symposium (IWS)

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