Avinash S. Kashyap scite author profile

This paper evaluates the capability of SiC power semiconductor devices, in particular JFET and Schottky barrier diodes (SBD) for application in high-temperature power electronics. SiC JFETs and SBDs were packaged in high temperature packages to measure the dc characteristics of these SiC devices at ambient temperatures ranging from 25 C (room temperature) up to 450 C. The results show that both devices can operate at 450 C, which is impossible for conventional Si devices, at the expense of significant derating. The current capability of the SiC SBD does not change with temperature, but as expected the JFET current decreases with rising temperatures. A 100V, 25W dc-dc converter is used as an example of a high-temperature power-electronics circuit because of circuit simplicity. The converter is designed and built in accordance with the static characteristics of the SiC devices measured under extremely high ambient temperatures, and then tested up to an ambient temperature of 400 C. The conduction loss of the SiC JFET increases slightly with increasing temperatures, as predicted from its dc characteristics, but its switching characteristics hardly change. Thus, SiC devices are well suited for operation in harsh temperature environments like aerospace and automotive applications. Index Terms-dc-dc converter circuit, device characterization, high temperature operation, packaging, silicon carbide (SiC) device. I. INTRODUCTION S ILICON CARBIDE (SiC) has several superior characteristics over silicon (Si) when used as a semiconductor material [1]-[6]. In particular, SiC semiconductor devices are expected

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Direct comparison of silicon and silicon carbide power transistors in high-frequency hard-switched applications

Glaser

Nasadoski

Losee

et al. 2011

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Power Conversion with SiC Devices at Extremely High Ambient Temperatures

Funaki

Balda

Junghans

et al.

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This paper evaluates the capability of SiC power semiconductor devices, in particular JFET and Schottky barrier diodes (SBD) for application in high-temperature power electronics. SiC JFETs and SBDs were packaged in high temperature packages to measure the dc characteristics of these SiC devices at ambient temperatures ranging from 25 C (room temperature) up to 450 C. The results show that both devices can operate at 450 C, which is impossible for conventional Si devices, at the expense of significant derating. The current capability of the SiC SBD does not change with temperature, but as expected the JFET current decreases with rising temperatures. A 100V, 25W dc-dc converter is used as an example of a high-temperature power-electronics circuit because of circuit simplicity. The converter is designed and built in accordance with the static characteristics of the SiC devices measured under extremely high ambient temperatures, and then tested up to an ambient temperature of 400 C. The conduction loss of the SiC JFET increases slightly with increasing temperatures, as predicted from its dc characteristics, but its switching characteristics hardly change. Thus, SiC devices are well suited for operation in harsh temperature environments like aerospace and automotive applications.Index Terms-dc-dc converter circuit, device characterization, high temperature operation, packaging, silicon carbide (SiC) device.

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A 55-kW Three-Phase Inverter With Si IGBTs and SiC Schottky Diodes

Ozpineci

Chinthavali

Tolbert

et al. 2009

IEEE Trans. on Ind. Applicat.

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A 55 kW Three-Phase Inverter with Si IGBTs and SiC Schottky Diodes

Ozpineci

Chinthavali

Tolbert

et al.

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