Abstract

SiC is a wide bandgap semiconductor with better electrothermal properties than silicon, including higher temperature of operation, higher breakdown voltage, lower losses and the ability to switch at higher frequencies. However, the power cycling performance of SiC devices in traditional silicon packaging systems is in need of further investigation since initial studies have shown reduced reliability. These traditional packaging systems have been developed for silicon, a semiconductor with different electrothermal and thermomechanical properties from SiC, hence the stresses on the different components of the package will change. Pressure packages, a packaging alternative where the weak elements of the traditional systems like wirebonds are removed, have demonstrated enhanced reliability for silicon devices however, there has not been much investigation on the performance of SiC devices in press-pack assemblies. This will be important for high power applications where reliability is critical. In this paper, SiC Schottky diodes in pressure packages have been evaluated, including the electrothermal characterisation for different clamping forces and contact materials, the thermal impedance evaluation and initial thermal cycling studies, focusing on the use of aluminium graphite as contact material.

Highlights

  • Power device packaging involves intimate contact between different materials with different thermomechanical properties

  • A packaging alternative where the elements of the packaging subjected to thermomechanical stresses are removed, achieving an enhanced reliability, is the press-pack modules [2]

  • Press-pack modules have typically been used in high power applications like HVDC line-commutated converters where series connected thyristors are required for high DC voltage blocking capability

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Summary

Introduction

Power device packaging involves intimate contact between different materials with different thermomechanical properties. Current packaging systems have been developed for silicon rather than silicon carbide the different thermomechanical properties of SiC lead to different stresses on the elements of the packaging system This results in a reduced power cycling capability of the current SiC devices compared with their silicon counterparts [1]. A packaging alternative where the elements of the packaging subjected to thermomechanical stresses are removed, achieving an enhanced reliability, is the press-pack modules [2]. There are few studies on the implementation of SiC in presspack [3,4], the availability of larger SiC dies and the limited reliability shown by the traditional packaging systems suggest that SiC press-pack modules could be a suitable alternative, considering the enhanced power cycling capability demonstrated in [4].

Prototype for the evaluation of silicon carbide devices in presspack
Initial measurements and considerations
Thermal impedance characterisation
Power cycling results
Conclusions

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