Power cycle method for accelerating bipolar degradation of SiC MOSFET body diode

A technology of power cycle and body diode, applied in the direction of single semiconductor device test, semiconductor working life test, measuring device, etc., can solve the problems of power cycle test control complexity, high cost, low aging efficiency, etc., to avoid thermal runaway, control Simple, accelerated effect of bipolar degeneration

Inactive Publication Date: 2020-03-24
XI AN JIAOTONG UNIV +1
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  • Description
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Problems solved by technology

The power cycle test control in this test method is complex and costly. Real-time junction temperature monitoring and more complex switch control are required to avoid the impact of factors such as thermal runaway on the package, and it is usually carried out at room temperature, and the aging efficiency is low.

Method used

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  • Power cycle method for accelerating bipolar degradation of SiC MOSFET body diode
  • Power cycle method for accelerating bipolar degradation of SiC MOSFET body diode
  • Power cycle method for accelerating bipolar degradation of SiC MOSFET body diode

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Embodiment Construction

[0022] The invention requires a power device analyzer Keysight B1505A, a double-pulse dynamic performance test system, a power semiconductor surge current test bench and a high-temperature oven.

[0023] refer to figure 1 Shown, the present invention comprises the following steps:

[0024] 1) Perform static characteristic tests on the SiC MOSFET discrete device 1 and SiC MOSFET discrete device 2 of the same type respectively, and measure the forward IV characteristics of their body diodes;

[0025] 2) Then test the dynamic characteristics of the above-mentioned SiC MOSFET discrete device 1 and SiC MOSFET discrete device 2, and measure the reverse recovery current waveform of their body diodes;

[0026] 3) Determine the repetitive surge current of an appropriate size. The surge current is 5-10 times the rated current of the SiC MOSFET discrete device, and conduct temperature evaluation of the power cycle at room temperature and high temperature to ensure that the SiC MOSFET di...

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Abstract

The invention discloses a power cycle method for accelerating bipolar degradation of a SiC MOSFET body diode, and the method comprises the steps: firstly determining a proper repeated surge current, and carrying out temperature evaluation of power cycle at normal temperature and high temperature; carrying out repeated surge current power cycle test on the body diode of an SiC MOSFET discrete device I at normal temperature; performing repeated surge current power cycle test on the body diode of an SiC MOSFET discrete device II of the same model at a high temperature; when the body diodes of theSiC MOSFET discrete device I and the SiC MOSFET discrete device II are aged to a certain degree, measuring degradation of static characteristics (forward IV characteristics) and dynamic characteristics (reverse recovery current waveform) of body diodes of the SiC MOSFET discrete device I and the SiC MOSFET discrete device I Repeated surge current power circulation at high temperature overcomes the limitation of direct current stress power circulation, is simple to control and high in reliability, has no continuous heat accumulation in the power circulation period, has no influence on packaging characteristics, can be carried out in a high-temperature environment, improves the aging efficiency and accelerates bipolar degradation.

Description

technical field [0001] The invention belongs to the field of SiC power semiconductor devices, in particular to a power cycle method for accelerating bipolar degradation of SiC MOSFET body diodes. Background technique [0002] Compared with the semiconductor Si material, the wide bandgap semiconductor SiC has a larger band gap (3 times that of Si), a higher thermal conductivity (3 times that of Si), a higher electron saturation velocity (2 times that of Si), etc. Excellent material properties, stronger temperature resistance and higher applicable frequency, are widely used in power electronic systems with high power density and high conversion efficiency. However, SiC bipolar power devices have the problem of bipolar degradation. When electron and hole recombination occurs in SiC power semiconductor devices for a long time and the recombination energy exceeds a certain value, SiC power semiconductor devices will age, and the pre-existing basal plane position Fault (BPD) expa...

Claims

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Application Information

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Patent Type & Authority Applications(China)
IPC IPC(8): G01R31/26
CPCG01R31/2601G01R31/2642
Inventor 王振宇李运甲孙晓华朱郑允郭清刘晔
Owner XI AN JIAOTONG UNIV
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