Single-Event Radiation Effects in Silicon Carbide Power MOSFETs
In this research, the radiation induced single event effects (SEE) observed in silicon
carbide (SiC) power MOSFETs have been studied. Heavy ions, terrestrial neutrons and
protons were selected as radiation environments to be investigated, as representative of
space, avionics and high-energy accelerator applications. SEE tests and electrical analysis
were performed in order to identify the modes and mechanisms of failure, and to assess
the reliability of commercial SiC MOSFET technologies. The research initially focused on
the non-catastrophic SEEs induced by heavy-ion irradiation, which represent a significant
risk for the part reliability in space applications. The broad-beam and microbeam results
pave the way to the understanding of the degradation mechanism, named single event
leakage current (SELC). Two types of degradation are described in this work, involving
different parts of the SiC MOSFET structure depending on the applied voltage during the
operation. At low bias the SELC is observed in the region under the gate oxide, whereas
for voltages over a certain threshold a second mechanism involving the p-n junction is
newly added. Heavy-ion latent damage effects were also studied through radiation tests
and scanning electron microscopy (SEM) analysis of the damaged site. Two mechanisms
were observed, involving the gate oxide and the SiC crystal lattice. Finally, the heavy-ion
SEEs are summarised as function of the operational bias and linear energy transfer
(LET). The second part of this work focused on SiC MOSFET reliability when exposed to
proton and terrestrial-neutron environments. Accelerated single event burnout tests were
performed using devices with different architectures. Electrical analysis of the damaged
devices was carried out to investigate the failure mechanism. The results provide useful
information about the reliability of the commercial SiC MOSFET technologies for avionic
and high-energy accelerator applications.
This project was carried out in the framework of a collaboration between the Physics
Department at the University of Jyväskylä, the radiation to electronics (R2E) project at the
European Council for Nuclear Research (CERN), and the Advanced Power Semiconductor
(APS) Laboratory at ETH Zürich.
Keywords: silicon carbide, power MOSFETs, radiation effects, Single Event Effects,
SELC, SEB, SEGR, latent damage
...
Publisher
Jyväskylän yliopistoISBN
978-951-39-8726-8ISSN Search the Publication Forum
2489-9003Contains publications
- Artikkeli I: Martinella, C., Stark, R., Ziemann, T., Alia, R. G., Kadi, Y., Grossner, U., & Javanainen, A. (2019). Current Transport Mechanism for Heavy-Ion Degraded SiC MOSFETs. IEEE Transactions on Nuclear Science, 66(7), 1702-1709. DOI: 10.1109/ICE.2018.8436340. JYX: jyx.jyu.fi/handle/123456789/65082
- Artikkeli II: Martinella, C., Ziemann, T., Stark, R., Tsibizov, A., Voss, K. O., Alia, R. G., Kadi, Y., Grossner, U., & Javanainen, A. (2020). Heavy-Ion Microbeam Studies of Single-Event Leakage Current Mechanism in SiC VD-MOSFETs. IEEE Transactions on Nuclear Science, 67(7), 1381-1389. DOI: 10.1109/TNS.2020.3002729
- Artikkeli III: Martinella, C., Alia, R. G., Stark, R., Coronetti, A., Cazzaniga, C., Kastriotou, M., Kadi, Y., Gaillard, R., Grossner, U., & Javanainen, A. (2021). Impact of Terrestrial Neutrons on the Reliability of SiC VD-MOSFET Technologies. IEEE Transactions on Nuclear Science, 68(5), 634-641. DOI: 10.1109/TNS.2021.3065122
- Artikkeli IV: Martinella, C., Natzke, P., Alia, R. G., Kadi, Y., Rossi, M., Jaatinen, J., Kettunen, H., Grossner, U., Javanainen, A. (2021). Heavy-ion Induced Single Event Effects and Latent Damages in SiC Power MOSFETs. Submitted for publication to Microelectronics Reliability.
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