2021
DOI: 10.35848/1347-4065/abf2a7
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Effects of incomplete ionization on forward current–voltage characteristics of p-type diamond Schottky barrier diodes based on numerical simulation

Abstract: The forward current–voltage characteristics of p-type diamond pseudo-vertical Schottky barrier diodes are investigated via numerical simulation. Impact ionization decrease the hole concentration of the p− drift layer from 1015 to 1014 cm–3 at 300 K, thereby increasing the forward voltage drop and on-resistance. When we consider an incomplete ionization with increasing temperature, the increase in the hole concentration is more dominant than the enhanced phonon scattering, thereby resulting in an increasing for… Show more

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Cited by 6 publications
(3 citation statements)
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“…From this doping density value, it is rather simple to calculate the corresponding resistivity of the channel layer using equation (1). The models for the free holes density [24,25], and the hole mobility [26] are dependent of the temperature, the boron-doping density and the compensation level in donor atoms. Note that, in this study, the compensation level, N d /N a , is set to 4 %.…”
Section: Descriptionmentioning
confidence: 99%
“…From this doping density value, it is rather simple to calculate the corresponding resistivity of the channel layer using equation (1). The models for the free holes density [24,25], and the hole mobility [26] are dependent of the temperature, the boron-doping density and the compensation level in donor atoms. Note that, in this study, the compensation level, N d /N a , is set to 4 %.…”
Section: Descriptionmentioning
confidence: 99%
“…Diamond, in contrast to 4H-SiC, suffers from incomplete ionization due to a high activation energy of the dopants [23], in the context of bulk conduction. Therefore, it is necessary to calculate the hole concentration as a function of the temperature, the compensation level and the p-type doping density.…”
Section: Analytical Modelingmentioning
confidence: 99%
“…This doping control and bulk conduction allow a controlled device optimization, a better reliability and replicability of the fabrication process. However, the diamond devices based on bulk conduction suffer from incomplete ionization, which increases the ON-state resistance at room temperature and below [23,24]. At high junction temperatures (e.g.…”
Section: Introductionmentioning
confidence: 99%