Daniel Baierhofer scite author profile

The quality of the silicon carbide (SiC) epitaxial layer, i.e., layer homogeneities and extended defect densities, is of highest importance for high power 4H-SiC trench metal-oxide-semiconductor field effect transistors (Trench-MOSFET) devices. Especially, yield for devices with a large chip area is severely impacted by extended defects. Previously, devices had to be fully manufactured to effectively gauge the impact of a reduction in extended defect densities in the epitaxial layers on device yield. The production of devices such as Trench-MOSFETs is an extensive procedure. Therefore, a correlation between extended defects in the epitaxial layer and electrical device failure would allow to reliably estimate the impact of process changes during epitaxial layer deposition on electrical device yield.For this reason, n-type epitaxial layers were grown on around 1,000 commercially available 150 mm 4H-SiC Si-face substrates, which received a chemical wet cleaning prior to the epitaxy deposition. Substrates with lowest micro-pipe density from two different suppliers were used. The wafers were characterized with the corresponding device layout for defects utilizing surface microscopy as well as ultraviolet photoluminescence techniques. Subsequently, these wafers were used to produce more than 500,000 Trench-MOSFET devices. All devices have been tested on wafer level for their initial electrical integrity.With these methods a precise correlation between extended defects in the epitaxial layer and electrical failures on wafer level could be found. The influence of different substrates on the defect-based yield prediction regarding the electrical yield on wafer level is discussed. Additionally, a calculated kill-ratio is presented and the severity of defect classes on initial device failure, e.g., stacking faults, and their key failures modes are discussed.

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Current SiC Power Device Development, Material Defect Measurements and Characterization at Bosch

Baierhofer

2019

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Defect Reduction in Epilayers for SiC Trench MOSFETs by Enhanced Epitaxial Growth

Baierhofer

Thomas

Staiger

et al. 2022

MSF

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The yield of high power 4H-SiC Trench-MOSFET devices, especially for those with large chip area, is largely dependent on the quality of the underlying epitaxial layers and therefore low densities of critical defects are of utmost importance. Different growth conditions for the deposition of epitaxial layers were investigated to reduce the impact of defects on electrical device performance. For this investigation, 12 μm thick n-type epitaxial layers were grown varying growth rates for the buffer and the drift layer in a warm-wall chemical vapor deposition reactor. The defects in the epitaxial layers were characterized utilizing surface microscopy as well as ultraviolet photoluminescence techniques. A quantitative comparison of surface defects and crystallographic defects between the different growth conditions was conducted with these methods. The impact of the growth conditions on the formation of critical defects is discussed in detail. The reduction of critical defects, which resulted in an increase of the predicted die yield, as well as an outlook on future investigations, is discussed.

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