New Insights into the Occurrence of Prismatic Slip during PVT Growth of SiC Crystals

Shan Shan Hu; Balaji Raghothamachar; Ze Yu Chen; Kevin W. Kayang; Dilip Gersappe; Michael Dudley; Victor Torres; Douglas Dukes; Diana Lang; Andy Martin; Hunter Briccetti; Samantha Griswold; Thomas Kegg; Nicholas Griffin

doi:10.4028/p-0Vb1Ug

Paper Titles

Thick Semi-Insulating 4H-SiC Layer Exfoliation for Non-Epitaxial Engineered Substrates
p.17

Lab-Based X-Ray Topography Characterization of Axial Samples from 4H-SiC Boules Grown by PVT Method
p.27

New Insights in Orientation and Growth of 150 mm GaN on SiC for HEMT
p.37

Process Gas Control for High-Resistance HPSI-SiC Growth
p.43

High-Temperature Adhesive Bonding of 4H-SiC Substrates
p.49

New Insights into the Occurrence of Prismatic Slip during PVT Growth of SiC Crystals
p.57

SmartSiC™ 150 & 200mm Engineered Substrate: Enabling SiC Power Devices with Improved Performances and Reliability
p.65

Development of a Novel Warpage Control Method for Epi-Ready 4H-SiC Wafers by Depositing Homoepitaxial Layers on both Si- and C-Faces
p.75

Improvement of the Yield during Crystal Growth of SiC by PVT by Proper Selection and Design of Hot Zone Isolation Components
p.83

HomeMaterials Science ForumMaterials Science Forum Vol. 1156New Insights into the Occurrence of Prismatic Slip...

New Insights into the Occurrence of Prismatic Slip during PVT Growth of SiC Crystals

Abstract:

Prismatic slip systems are the secondary slip systems in Silicon carbide (4H-SiC) crystals. The previously proposed radial thermal model of the PVT growth process for SiC crystals, which predicts the occurrence of slip in different prismatic planes as a function of the radial position in the boule, has been shown to generally work well. Recent observations of growth interface nucleation of prismatic slip necessitated updating the thermal model to incorporate the effects of the curvature of the growth interface. A 3D finite element model has been developed to include the growth interface curvature complexity. The model predicts high dislocation densities due to prismatic slip near the peripheral regions dropping to zero near the center for wafers from sections of the boule grown with a flatter interface and a less dense distribution of prismatic slip dislocations that extends to the center for wafers from boule sections grown with a more convex interface. Additionally, due to such an interface-initiated prismatic slip, , the asymmetrical step configuration produced by off-axis growth results in an asymmetrical distribution of prismatic slip. The studies suggest that a reduced surface curvature is necessary to suppress the prevalence of interface-related prismatic slip generation.

By email View Pdf

You have full access to the following eBook

Read eBook

Info:

Periodical:

Materials Science Forum (Volume 1156)

Pages:

57-64

DOI:

https://doi.org/10.4028/p-0Vb1Ug

Citation:

Cite this paper

Online since:

September 2025

Authors:

Shan Shan Hu*, Balaji Raghothamachar, Ze Yu Chen, Kevin W. Kayang, Dilip Gersappe, Michael Dudley, Victor Torres, Douglas Dukes, Diana Lang, Andy Martin, Hunter Briccetti, Samantha Griswold, Thomas Kegg, Nicholas Griffin

Keywords:

4H-SiC, Prismatic Slip, PVT Growth, X-Ray Topography

Export:

RIS, BibTeX

Permissions:

Creative Commons CC BY 4.0

Citation:

* - Corresponding Author

References

[1] H. Matsunami, T. Kimoto, Step-controlled epitaxial growth of SiC: High quality homoepitaxy, Mater. Sci. Eng. R Rep. 20 (1997) 125-166.

DOI: 10.1016/s0927-796x(97)00005-3

Google Scholar

[2] R. SIngh, M. PEchT, Commercial impact of silicon carbide, IEEE Ind. Electron. Mag. 2 (2008) 19-31.

DOI: 10.1109/mie.2008.928617

Google Scholar

[3] S. Ha, N. T. Nuhfer, G. S. Rohrer, M. De Graef, M. Skowronski, Identification of prismatic slip bands in 4H SiC boules grown by physical vapor transport, J. Electron. Mater. 29 (2000) L5-L8.

DOI: 10.1007/s11664-000-0194-1

Google Scholar

[4] H. H. Wang, S. Y. Byrapa, F. Wu, B. Raghothamachar, M. Dudley, E. Sanchez, D. M. Hansen, R. Drachev, S. G. Mueller, M. J. Loboda, Basal plane dislocation multiplication via the hopping frank-read source mechanism and observations of prismatic glide in 4H-SiC, Mater Sci Forum 717 (2012) 327-330.

DOI: 10.4028/www.scientific.net/msf.717-720.327

Google Scholar

[5] H. Wang, Studies of growth mechanism and defect origins in 4H-silicon carbide substrates and homoepitaxial layers, dissertation, Stony Brook University. 2014.

Google Scholar

[6] S. Hu, H. Fang, Y. Liu, H. Peng, T. Ailihumaer, Q. Cheng, Z. Chen, R. Dalmau, J. Britt, R. Schlesser, Prismatic slip in AlN crystals grown by PVT, ECS Transactions 104 (2021) 57-64.

DOI: 10.1149/10407.0057ecst

Google Scholar

[7] S. Hu, H. Fang, Y. Liu, H. Peng, Q. Cheng, Z. Chen, R. Dalmau, J. Britt, R. Schlesser, B. Raghothamachar, Characterization of prismatic slip in PVT-grown AlN crystals, J. Cryst. Growth 584 (2022) 126548.

DOI: 10.1016/j.jcrysgro.2022.126548

Google Scholar

[8] J. Guo, Y. Yang, B. Raghothamachar, J. Kim, M. Dudley, G. Chung, E. Sanchez, J. Quast, I. Manning, Prismatic slip in PVT-grown 4H-SiC crystals, J. Electron. Mater. 46 (2017) 2040-2044.

DOI: 10.1007/s11664-016-5118-9

Google Scholar

[9] J. Guo, Y. Yang, O. Y. Goue, B. Raghothamachar, M. Dudley, Study on the role of thermal stress on prismatic slip of dislocations in 4H-SiC crystals grown by PVT method, ECS Transactions 75 (2016) 163-168.

DOI: 10.1149/07512.0163ecst

Google Scholar

[10] M. Smith, ABAQUS/standard user's manual, version 6.9, (2009).

Google Scholar