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"Tae-Yong Park"

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"Tae-Yong Park"

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Early Stage Report: Graduate Research

Growth of Beta-Phase Gallium Oxide Thin Films on Off-Axis Sapphire Substrates by Mist Chemical Vapor Deposition
Jae-Hyeok Lim, Tae-Yong Park, Yun-Ji Shin, Seong-Min Jeong, Chang-Mo Kang, Si-Young Bae
J Electr Electron Mater 2026;39(3):302-308.
Published online May 1, 2026
DOI: https://doi.org/10.4313/JEEM.2026.39.3.10
β-Ga2O3 is an ultra-wide bandgap semiconductor promising for high-power electronic applications; however, heteroepitaxial growth on sapphire is challenging lattice and symmetry mismatch. In this study, β-Ga2O3 thin films were grown on C-plane sapphire substrates with various off-axis angles (0–12°) using mist-CVD, and the influence of substrate miscut on structural and optical properties was investigated. All films grown at 900°C exhibited (-201) oriented β phase. The crystal quality was strongly dependent on the off-axis angle, with intermediate off-axis angles (Δa = 6–8°) showing the narrowest rocking curve width. Off-axis substrates promoted step-aligned growth behavior compared to on-axis growth. Optical measurements revealed enhanced transmittance and wider bandgap values (4.92–4.95 eV) for off-axis samples compared to the on-axis film (4.69 eV). The findings provide practical guidelines for optimizing heteroepitaxial β-Ga2O3 growth on low-cost sapphire substrates for high-performance device applications.
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Effect of Radiation Heat Transfer on the Control of Temperature Gradient in the Induction Heating Furnace for Growing Single Crystals
Tae-yong Park, Yun-ji Shin, Minh-tan Ha, Si-young Bae, Young-soo Lim, Seong-min Jeong
J Electr Electron Mater 2019;32(6):522-527.   Published online November 1, 2019
In order to fabricate high-quality SiC substrates for power electronic devices, various single crystal growing methods were prepared. These include the physical vapor transport (PVT) and top seeded solution growth (TSSG) methods. All the suggested SiC growth methods generally use induction-heating furnaces. The temperature distribution in this system can be easily adjusted by changing the hot-zone design. Moreover, precise temperature control in the induction-heating furnace is favorably required to grow a high-quality crystal. Therefore, in this study, we analyzed the heat transfer in these furnaces to grow SiC crystals. As the growth temperature of SiC crystals is very high, we evaluated the effect of radiation heat transfer on the temperature distribution in induction-heating furnaces. Based on our simulation results, a heat transfer strategy that controls the radiation heat transfer was suggested to obtain the optimal temperature distribution in the PVT and TSSG methods.
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