Title :
Physical based Schottky barrier diode modeling for THz applications
Author :
Yan, Lijun ; Krozer, V. ; Michaelsen, Rasmus ; Djurhuus, T. ; Johansen, Tom K.
Author_Institution :
Dept. of Electr. Eng., Tech. Univ. of Denmark, Lyngby, Denmark
Abstract :
In this work, a physical Schottky barrier diode model is presented. The model is based on physical parameters such as anode area, Ohmic contact area, doping profile from epitaxial (EPI) and substrate (SUB) layers, layer thicknesses, barrier height, specific contact resistance, and device temperature. The effects of barrier height lowering, nonlinear resistance from the EPI layer, and hot electron noise are all included for accurate characterization of the Schottky diode. To verify the diode model, measured I-V and C-V characteristics are compared with the simulation results. Due to the lack of measurement data for noise behaviors, simulated noise temperature is compared with the experimental data found from the open literature.
Keywords :
Schottky diodes; contact resistance; doping profiles; hot carriers; ohmic contacts; semiconductor device models; semiconductor epitaxial layers; C-V characteristics; I-V characteristics; Ohmic contact area; THz applications; anode area; barrier height; device temperature; doping profile; epitaxial layers; hot electron noise; layer thicknesses; nonlinear resistance; physical based Schottky barrier diode modeling; simulated noise temperature; specific contact resistance; substrate layers; Anodes; Capacitance; Junctions; Noise; Schottky barriers; Schottky diodes; Temperature measurement; Schottky barrier diode; barrier height lowering; hot-electron noise; physical based model;
Conference_Titel :
Wireless Symposium (IWS), 2013 IEEE International
Conference_Location :
Beijing
DOI :
10.1109/IEEE-IWS.2013.6616741
