Filling-Design Effect of Powder Source in the Crucible on SiC Single-Crystal Growth

Min Kyu Kang; Gi Uk Lee; Ye Jin Choi; Gyeoung Jun Song; Na Kyeoung Kim; Mi Seon Park; Kwang Hee Jung; Won Jae Lee

doi:10.4028/p-Yddrs7

Paper Titles

Preface

Filling-Design Effect of Powder Source in the Crucible on SiC Single-Crystal Growth
p.1

Nitrogen Dopant Incorporation into Epitaxial 4H-SiC and the Influence of CVD Growth Parameters
p.9

Epitaxial SiC Development for High Nitrogen Incorporation
p.17

The 4H-SiC Epitaxy Study of Ammonia Doping
p.23

Formation of Alternating Epilayers of 4H-SiC and 3C-SiC by Simultaneous Lateral Epitaxy
p.33

Predictive Doping and Thickness Analysis of a Multi-Wafer SiC Warm-Wall Epi Reactor for Improved Layer Cpks
p.43

Recent Advancement in Noncontact Wafer Level Electrical Characterization for WBG Technologies
p.49

Active Planarization Method from Rough Surface of 4º-off 4H-SiC (0001) Controlled by Step Bunching and Debunching Mechanism Using Dynamic AGE-ing^®
p.57

HomeMaterials Science ForumMaterials Science Forum Vol. 1157Filling-Design Effect of Powder Source in the...

Filling-Design Effect of Powder Source in the Crucible on SiC Single-Crystal Growth

Abstract:

An effective powder consumption is indispensable for enlarging the diameter and thickness of SiC crystals. We employed three types of filling designs for SiC source powder with different distances between the surface of the seed and the source powder. To maintain the shape of the designs, the SiC source powder was heat-treated in an Ar atmosphere at 680 torr within a temperature range of 1500 to 1600°C. The SiC source powder consumption and contribution to growth in well-structured layouts increased due to the increase in the surface area of SiC source powder, despite its lower initial powder filling. The numerical simulation showed that the well-structured layouts with a higher surface area of SiC source powder have a higher partial pressure of Si and SiC₂ gases (supersaturation of these gas phases) near the seed region compared to the without well-structured layouts. The computed tomography (CT) analysis of the cross-section of SiC source powder after the growth run clearly showed that the source powder was previously sublimated at the region of the crucible wall, and recrystallization at the surface region of the source powder physically retarded the pathway of SiC source gases to the region of the SiC seed crystal. The newly designed well-structured layouts of the source powder have an economical advantage in achieving effective powder consumption during crystal growth.

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Periodical:

Materials Science Forum (Volume 1157)

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1-7

DOI:

https://doi.org/10.4028/p-Yddrs7

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Online since:

September 2025

Authors:

Min Kyu Kang, Gi Uk Lee, Ye Jin Choi, Gyeoung Jun Song, Na Kyeoung Kim, Mi Seon Park, Kwang Hee Jung, Won Jae Lee*

Keywords:

Computed Tomography, Crucible Design, Growth Contribution, Numerical Simulation, Physical Vapor Transport (PVT), Powder Consumption, SiC, Source Powder, Supersaturation, Surface Area

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