Gate Switching Instability in Silicon Carbide MOSFETs—Part II: Modeling

Timor Grasser; Maximilian Feil; Katja Waschneck; Hans Reisinger; Judith Berens; Dominic Waldhör; Aleksandr Vasilev; Michael Waltl; Thomas Aichinger; Michel Bockstedte; Wolfgang Gustin; Gregor Pobegen

doi:10.1109/TED.2024.3397629

Gate Switching Instability in Silicon Carbide MOSFETs—Part II: Modeling

Timor Grasser, Maximilian Feil, Katja Waschneck, Hans Reisinger, Judith Berens, Dominic Waldhör, Aleksandr Vasilev, Michael Waltl, Thomas Aichinger, Michel Bockstedte, Wolfgang Gustin, Gregor Pobegen

Department of Many Particle Systems

Research output: Contribution to journal › Article › peer-review

Abstract

It has recently been observed that bipolar switching between accumulation and inversion can result in an unexpected threshold voltage drift in SiC MOSFETs. This phenomenon has been termed gate switching instability (GSI) and is characterized by power-law time exponents close to unity, significantly larger than what is typically observed for ordinary bias temperature instability (BTI) during static or unipolar switching stress. Since the bias, frequency, and temperature dependence of GSI are the same as what is seen in charge pumping (CP) experiments, we stipulate that recombination events at the interface lead to recombination-enhanced defect reactions (REDRs), which can eventually lead to degradation. Based on these observations, we develop a comprehensive physical model for GSI, discuss its features, derive a closed form analytical solution, and finally validate the model against detailed experimental data.

Original language	English
Pages (from-to)	4218-4226
Number of pages	9
Journal	IEEE Transaction on Electronic devices
Volume	71
Issue number	7
DOIs	https://doi.org/10.1109/TED.2024.3397629
Publication status	Published - 01 Jul 2024

Fields of science

103 Physics, Astronomy

JKU Focus areas

Digital Transformation

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10.1109/TED.2024.3397629

Cite this

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title = "Gate Switching Instability in Silicon Carbide MOSFETs—Part II: Modeling",

abstract = "It has recently been observed that bipolar switching between accumulation and inversion can result in an unexpected threshold voltage drift in SiC MOSFETs. This phenomenon has been termed gate switching instability (GSI) and is characterized by power-law time exponents close to unity, significantly larger than what is typically observed for ordinary bias temperature instability (BTI) during static or unipolar switching stress. Since the bias, frequency, and temperature dependence of GSI are the same as what is seen in charge pumping (CP) experiments, we stipulate that recombination events at the interface lead to recombination-enhanced defect reactions (REDRs), which can eventually lead to degradation. Based on these observations, we develop a comprehensive physical model for GSI, discuss its features, derive a closed form analytical solution, and finally validate the model against detailed experimental data.",

author = "Timor Grasser and Maximilian Feil and Katja Waschneck and Hans Reisinger and Judith Berens and Dominic Waldh{\"o}r and Aleksandr Vasilev and Michael Waltl and Thomas Aichinger and Michel Bockstedte and Wolfgang Gustin and Gregor Pobegen",

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T1 - Gate Switching Instability in Silicon Carbide MOSFETs—Part II: Modeling

AU - Grasser, Timor

AU - Feil, Maximilian

AU - Waschneck, Katja

AU - Reisinger, Hans

AU - Berens, Judith

AU - Waldhör, Dominic

AU - Vasilev, Aleksandr

AU - Waltl, Michael

AU - Aichinger, Thomas

AU - Bockstedte, Michel

AU - Gustin, Wolfgang

AU - Pobegen, Gregor

PY - 2024/7/1

Y1 - 2024/7/1

N2 - It has recently been observed that bipolar switching between accumulation and inversion can result in an unexpected threshold voltage drift in SiC MOSFETs. This phenomenon has been termed gate switching instability (GSI) and is characterized by power-law time exponents close to unity, significantly larger than what is typically observed for ordinary bias temperature instability (BTI) during static or unipolar switching stress. Since the bias, frequency, and temperature dependence of GSI are the same as what is seen in charge pumping (CP) experiments, we stipulate that recombination events at the interface lead to recombination-enhanced defect reactions (REDRs), which can eventually lead to degradation. Based on these observations, we develop a comprehensive physical model for GSI, discuss its features, derive a closed form analytical solution, and finally validate the model against detailed experimental data.

AB - It has recently been observed that bipolar switching between accumulation and inversion can result in an unexpected threshold voltage drift in SiC MOSFETs. This phenomenon has been termed gate switching instability (GSI) and is characterized by power-law time exponents close to unity, significantly larger than what is typically observed for ordinary bias temperature instability (BTI) during static or unipolar switching stress. Since the bias, frequency, and temperature dependence of GSI are the same as what is seen in charge pumping (CP) experiments, we stipulate that recombination events at the interface lead to recombination-enhanced defect reactions (REDRs), which can eventually lead to degradation. Based on these observations, we develop a comprehensive physical model for GSI, discuss its features, derive a closed form analytical solution, and finally validate the model against detailed experimental data.

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DO - 10.1109/TED.2024.3397629

M3 - Article

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SP - 4218

EP - 4226

JO - IEEE Transaction on Electronic devices

JF - IEEE Transaction on Electronic devices

IS - 7

ER -

Gate Switching Instability in Silicon Carbide MOSFETs—Part II: Modeling

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