London Met Repository

Theory and experiment for silicon Schottky barrier diodes at high current density

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Brinson, Mike, Wilkinson, J. M. and Wilcock, J. D. (1977) Theory and experiment for silicon Schottky barrier diodes at high current density. Solid State Electronics, 20 (1). pp. 45-50. ISSN 0038-1101

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Abstract

Metal-silicon Schottky barrier diodes exhibit n values which theoretically vary as a function of doping and applied voltage. The expected variation depends on which theoretical model is used to describe the current transport.

Titanium n-type silicon barriers were prepared. At a doping level of 3 × 1015 cm−3 the barrier height and n-value measured at 100 mV were 0.485±0.005 V and 1.02±0.01 whereas for a doping level of 2 × 1014 cm−3 the corresponding values were 0.500±0.005 V and 1.18±0.05.

The experimental variation of the diode n value as a function of semiconductor band bending showed good agreement with the thermionic-diffusion model of Crowell and Beguwala: n values increased rapidly as the band bending β → 2, and n values were highest at a given β for diodes with the lowest doping concentration. Similar results were obtained by measurements on magnesium and aluminium barriers on n-type silicon.

An analysis of the results has shown that the variation of the diode saturation current Is follows the predictions of the thermionic-diffusion theory, although there were some anomalies at high current densities. The anomalies did not result from variation of the width of the undepleted region of the epitaxial silicon layer or from diode self-heating effects.

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