An analog to digital converter in a SiC CMOS technology for high-temperature applications

Jiarui Mo; Yunfan Niu; Alexander May; Mathias Rommel; Chiara Rossi; Joost Romijn; Guoqi Zhang; Sten Vollebregt

doi:10.1063/5.0195013

An analog to digital converter in a SiC CMOS technology for high-temperature applications

Jiarui Mo, Yunfan Niu, Alexander May, Mathias Rommel, Chiara Rossi, Joost Romijn, Guoqi Zhang, Sten Vollebregt^*

^*Corresponding author for this work

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Abstract

Integrated circuits based on wide bandgap semiconductors are considered an attractive option for meeting the demand for high-temperature electronics. Here, we report an analog-to-digital converter fabricated in a silicon carbide complementary metal-oxide-semiconductor technology now available through Europractice. The MOSFET component in this technology was measured up to 500 °C, and the key parameters, such as threshold voltage, field-effect mobility, and channel-length modulation parameters, were extracted. A 4-bit flash data converter, consisting of 266 transistors, is implemented with this technology and demonstrates correct operation up to 400 °C. Finally, the gate oxide quality is investigated by time-dependent dielectric breakdown measurements at 500 °C. A field-acceleration factor of 4.4 dec/(MV/cm) is obtained by applying the E model.

Original language	English
Article number	152105
Number of pages	6
Journal	Applied Physics Letters
Volume	124
Issue number	15
DOIs	https://doi.org/10.1063/5.0195013
Publication status	Published - 2024

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152105_1_5.0195013Final published version, 3.46 MBLicence: CC BY

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abstract = "Integrated circuits based on wide bandgap semiconductors are considered an attractive option for meeting the demand for high-temperature electronics. Here, we report an analog-to-digital converter fabricated in a silicon carbide complementary metal-oxide-semiconductor technology now available through Europractice. The MOSFET component in this technology was measured up to 500 °C, and the key parameters, such as threshold voltage, field-effect mobility, and channel-length modulation parameters, were extracted. A 4-bit flash data converter, consisting of 266 transistors, is implemented with this technology and demonstrates correct operation up to 400 °C. Finally, the gate oxide quality is investigated by time-dependent dielectric breakdown measurements at 500 °C. A field-acceleration factor of 4.4 dec/(MV/cm) is obtained by applying the E model.",

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AU - Mo, Jiarui

AU - Niu, Yunfan

AU - May, Alexander

AU - Rommel, Mathias

AU - Rossi, Chiara

AU - Romijn, Joost

AU - Zhang, Guoqi

AU - Vollebregt, Sten

PY - 2024

Y1 - 2024

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AB - Integrated circuits based on wide bandgap semiconductors are considered an attractive option for meeting the demand for high-temperature electronics. Here, we report an analog-to-digital converter fabricated in a silicon carbide complementary metal-oxide-semiconductor technology now available through Europractice. The MOSFET component in this technology was measured up to 500 °C, and the key parameters, such as threshold voltage, field-effect mobility, and channel-length modulation parameters, were extracted. A 4-bit flash data converter, consisting of 266 transistors, is implemented with this technology and demonstrates correct operation up to 400 °C. Finally, the gate oxide quality is investigated by time-dependent dielectric breakdown measurements at 500 °C. A field-acceleration factor of 4.4 dec/(MV/cm) is obtained by applying the E model.

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An analog to digital converter in a SiC CMOS technology for high-temperature applications

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