Parameter Extraction and Geometry Optimisation of Planar Schottky Diodes
Paper in proceeding, 2010

The continuous interests in terahertz (300 GHz to 10 THz) applications have generated technology pressure in the search of reliable, room temperature operational and compact sources and detectors. Various terahertz sources such as optically pumped lasers, backward wave oscillators, and direct multiplied sources have been explored [1]. For direct multiplied sources, the GaAs-based Schottky diode is one of the most critical devices in heterodyne receivers operating at millimetre and sub-millimetre wavelengths. The importance of Schottky diode could be seen from the meticulous efforts in the diode technology advancement. This includes the evolvement of the whisker contact to the surface channel planar diode technology [2] as well as the circuit integration of the discrete Schottky diodes. For high frequency applications, the performance of a GaAs Schottky diode is limited by the parasitic elements [3] and the losses due to skin effects [4]. Thus, systematic studies of the Schottky diode parasitic elements and high frequency losses are very crucial in meeting the design goals. In the search of optimised diode performance, several studies on diode modelling have been performed [5], [6]. In this paper, we present a systematic method to estimate the diode geometry dependent parasitic elements and skin effect losses for diodes operating up to 400 GHz. Different diode geometries, such as padto- pad distance, buffer layer thickness and semi-insulating etch depth have been investigated. The equivalent circuit based method as in [7] has been used, where the parasitic elements are extracted through the least square error fitting of the S-parameters simulated in Ansoft HFSS simulator to the lumped equivalent circuit. Simulations are performed with the semi-insulating substrate of 3 μm (for the case of integrated diode on the membrane) and 10 μm (for the case of discrete diode). In addition, high frequency losses are investigated with the similar method, by using lossy conductors and adding a frequency dependent resistor in the lumped equivalent circuit. Analysis of the simulation and measurement results will be presented.

Author

Aik-Yean Tang

Chalmers, Applied Physics, Physical Electronics

Peter Sobis

Chalmers, Applied Physics, Physical Electronics

Vladimir Drakinskiy

Chalmers, Applied Physics, Physical Electronics

Huan Zhao Ternehäll

Chalmers, Applied Physics, Physical Electronics

Jan Stake

Chalmers, Applied Physics, Physical Electronics

21st International Symposium on Space Terahertz Technology 2010, ISSTT 2010; Oxford; United Kingdom; 23 March 2010 through 25 March 2010

361-
978-161782362-6 (ISBN)

Areas of Advance

Information and Communication Technology

Nanoscience and Nanotechnology

Subject Categories

Other Electrical Engineering, Electronic Engineering, Information Engineering

ISBN

978-161782362-6

More information

Created

10/7/2017