Paper Titles
Advanced Defects Study and Monitoring in New Generation 4H-SiC Devices
p.39
Investigating the Temperature Dependence of Charge Carrier Lifetime in Low-Doped Epitaxial 4H-SiC Layers
p.45
Investigation of Micropipe Defects and Their Strain Field Distortions in SiC Substrates Using X-Ray Topography
p.53
High Quality P-Type 4H-SiC Growth by PVT Method
p.59
Characterization of Deep Levels Introduced by Energy Filtered Ion Implantation with DLTS and MCTS in 4H-SiC
p.65
Observation and Analysis of the “Galaxy” Defect in 4H-SiC through X-Ray Synchrotron Topography
p.73
Growth and Characterization of High-Quality Thick Epitaxial 4H-SiC Wafers for High Voltage Devices
p.79
Silicon Carbide Epitaxial Defects and Substrate Defects Analysis by Dynamic Photoluminescence and X-Ray Topography
p.87
Unveiling the Role of Crystallographic Defects in SiC Device Reliability with Multi Modal Structural Analysis
p.93

Growth and Characterization of High-Quality Thick Epitaxial 4H-SiC Wafers for High Voltage Devices

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Abstract:

Silicon carbide is a leading wide-bandgap semiconductor for high-voltage power electronics. For 6.5–10 kV operation, thick epitaxial layers (≥60 µm) are required to sustain depletion width and maintain uniform electric fields, placing a premium on low extended-defect densities in both substrate and epilayer. Thick epitaxial 4H-SiC layers of 60 µm and 110 µm were grown on 6-inch substrates in a multi-wafer warm-wall reactor and evaluated by synchrotron X-ray topography in grazing-incidence (22-4 16) and transmission (11-20) geometries. Transmission imaging showed substrate dislocation content near the lower bound typically reported for 6-inch wafers. Notably, grazing-incidence topography (penetration depth >40 µm) revealed no basal-plane dislocations propagating into the epilayers, consistent with efficient dislocation conversion at the substrate–epilayer interface. The 3C-SiC inclusion density was ~30 per 6-inch wafer for 60 µm epilayers and ~60 per wafer for 110 µm epilayers; the average micropipes density varies from 0 to 5 for both 60 and 110 um epiwafers. Threading dislocation densities—screw, edge, and mixed—were on the order of 1.0–2.0 × 10³ cm⁻². These results establish thick 4H-SiC epilayers with suppressed basal-plane propagation and substantially reduced extended-defect content, providing a strong basis for reliable 6.5–10 kV device fabrication.

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Periodical:

Defect and Diffusion Forum (Volume 452)

Pages:

79-85

DOI:

https://doi.org/10.4028/p-mYaQQ1

Citation:

Cite this paper

Online since:

May 2026

Authors:

Yu Zhuo Li*, Jian Pei Zhang, Ze Yu Chen, Hao Chi Wang, Kai Xuan Zhang, Shan Shan Hu, Balaji Raghothamachar, Albert A. Burk Jr, Kanwar Singh, Muhammad Ali Johar, Nadeemullah A. Mahadik, Robert E. Stahlbush, Michael Dudley

Keywords:

3C Inclusions, Silicon Carbide, Thick Epitaxial Layer, X-Ray Topography

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* - Corresponding Author

References

[1] T. Kimoto, Material science and device physics in SiC technology for high-voltage power devices, Jpn. J. Appl. Phys. 54, 040103 (2015).

DOI: 10.7567/jjap.54.040103

Google Scholar

[2] Y. Zhang, H. Peng, Z. Chen, and M. Dudley, Investigation of factors influencing the occurrence of 3C-inclusions for the thick growth of on-axis C-face 4H-SiC epitaxial layers, J. Cryst. Growth 512, 1 (2019).

DOI: 10.3390/ma13214818

Google Scholar

[3] K. Masumoto, K. Kojima, and H. Yamaguchi, Investigation of Factors Influencing the Occurrence of 3C-Inclusions for the Thick Growth of On-Axis C-Face 4H-SiC Epitaxial Layers, Materials 13, 4818 (2020).

DOI: 10.3390/ma13214818

Google Scholar

[4] M. Dudley, N. Zhang, Y. Zhang, B. Raghothamachar, S. Y. Byrapa, G. Choi, E. Sanchez, D. M. Hansen, R. Drachev, and M. J. Loboda, Characterization of 100 mm diameter 4H-silicon carbide crystals with extremely low basal plane dislocation density, Mater. Sci. Forum 645–648, 291 (2010).

DOI: 10.4028/www.scientific.net/msf.645-648.291

Google Scholar

[5] B. Raghothamachar, M. Dudley, Dislocations in 4H-SiC Substrates and Epilayers, in: P. Wellmann, N. Ohtani, R. Rupp (Eds.), Wide Bandgap Semiconductors for Power Electronics, Wiley VCH GmbH, Weinheim, 2022, pp.169-198.

DOI: 10.1002/9783527824724.ch7

Google Scholar

[6] Z. Chen, Y. Liu, Q. Cheng, S. Hu, B. Raghothamachar, and M. Dudley, Analysis of strain in ion implanted 4H-SiC by fringes observed in synchrotron X-ray topography, J. Cryst. Growth 627, 127535 (2024).

DOI: 10.1016/j.jcrysgro.2023.127535

Google Scholar

[7] M. Dudley, N. Zhang, Y. Zhang, B. Raghothamachar, and E. K. Sanchez, Nucleation of c-axis screw dislocations at substrate surface damage during 4H-SiC homo-epitaxy, Mater. Sci. Forum 645–648, 295 (2010).

DOI: 10.4028/www.scientific.net/msf.645-648.295

Google Scholar

[8] S. Ha, P. Mieszkowski, M. Skowronski, and L. B. Rowland, Dislocation conversion in 4H silicon carbide epitaxy, J. Cryst. Growth 244, 257 (2002).

DOI: 10.1016/s0022-0248(02)01706-2

Google Scholar

[9] H. Tsuchida, T. Miyanagi, I. Kamata, Y. Sugawara, et al., Investigation of basal plane dislocations in the 4H-SiC epilayers grown on {0001} substrates, Mater. Sci. Forum 483–485, 97 (2005).

DOI: 10.4028/www.scientific.net/msf.483-485.97

Google Scholar

[10] M.E. Liao, N. A. Mahadik, R. E. Stahlbush, A. Burk, U. Chakrabarti, I. Zwieback, X. Xu, and R. Rengarajan, Structural analysis of novel butterfly-shaped defects in 4H-SiC substrates, Proc. ICSCRM 2023 (2023).

Google Scholar

[11] Q. Cheng, H. Peng, B. Raghothamachar, and M. Dudley, Scratch-induced threading dislocations in thick 4H-SiC epilayers, Defect Diffus. Forum 434, 71 (2024).

Google Scholar