Impact of neutron radiation induced defects on the surge current robustness of silicon carbide P-intrinsic-N diodes

Haoshu Tan; Lin Zhang; Zhiqiang Li; Jun Tao Li; Peng Dong

doi:10.1002/elt2.64

Electron ›› 2025, Vol. 3 ›› Issue (1) : e64 DOI: 10.1002/elt2.64

RESEARCH ARTICLE

Impact of neutron radiation induced defects on the surge current robustness of silicon carbide P-intrinsic-N diodes

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Abstract

Surge current (SC) capability is one of the main aspects of reliability for silicon carbide (SiC) power devices. In this work, the influences of neutron radiation-induced defects on the SC capability and reliability of SiC P-intrinsic-N (PiN) diodes were comprehensively investigated. It was found that the surge capability of the diodes can be deteriorated even under the slightly enhanced formation of carbon-vacancy-related Z_1/2 and EH_6/7 defects introduced by neutron irradiation. Surprisingly, it was found that the forward voltage (V_F) decreases with the increased SC and the stress cycles in the irradiated diodes, which is usually found to increase under the SC tests and attributed to the bipolar degradation (BPD). By using technology computer-aided design simulation and deep-level transient spectroscopy characterization, it was found that the significant self-heating during surge stress leads to the annealing effect on the Z_1/2 defects through the promoted recombination with the nearest and second neighbor carbon interstitials injected by irradiation, which thus plays a dominant role in the decrease of V_F over the BPD.

Keywords

defects generation / degradation mechanism / neutron irradiation / SiC PiN diodes / surge current stress

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Haoshu Tan, Lin Zhang, Zhiqiang Li, Jun Tao Li, Peng Dong. Impact of neutron radiation induced defects on the surge current robustness of silicon carbide P-intrinsic-N diodes. Electron, 2025, 3(1): e64 DOI:10.1002/elt2.64

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