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Fabrication and Characterisitics of Al2O3-SiC Ceramic Composites for Electrostatic Discharge Safe Components
Ha-Neul Kim, Hyun-Myung Oh, Young-Jo Park, Jae-Woong Ko, Hyun-Kwuon Lee
J Korean Powder Metall Inst. 2018;25(2):144-150.   Published online April 1, 2018
DOI: https://doi.org/10.4150/KPMI.2018.25.2.144
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AbstractAbstract PDF

Al2O3-SiC ceramic composites are produced using pressureless sintering, and their plasma resistance, electrical resistance, and mechanical properties are evaluated to confirm their applicability as electrostatic-discharge-safe components for semiconductor devices. Through the addition of Mg and Y nitrate sintering aids, it is confirmed that even if SiC content exceeded 10%, complete densification is possible by pressureless sintering. By the uniform distribution of SiC, the total grain growth is suppressed to about 1 μm; thus an Al2O3-SiC sintered body with a high strength over 600 MPa is obtained. The optimum amount of SiC to satisfy all the desired properties of electrostaticdischarge-safe ceramic components is obtained by finding the correlation between the plasma resistance and the electrical resistivity as a function of SiC amount.

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Densification and Nanocrystallization of Water-Atomized Pure Iron Powder Using High Pressure Torsion
Eun-Yoo Yoon, Dong-Jun Lee, Ha-Neul Kim, Hee-Soo Kang, Eon-Sik Lee, Hyoung-Seop Kim
J Korean Powder Metall Inst. 2011;18(5):411-416.
DOI: https://doi.org/10.4150/KPMI.2011.18.5.411
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In this study, powder metallurgy and severe plastic deformation by high-pressure torsion (HPT) approaches were combined to achieve both full density and grain refinement at the same time. Water-atomized pure iron powders were consolidated to disc-shaped samples at room temperature using HPT of 10 GPa up to 3 turns. The resulting microstructural size decreases with increasing strain and reaches a steady-state with nanocrystalline (down to ~250 nm in average grain size) structure. The water-atomized iron powders were deformed plastically as well as fully densified, as high as 99% of relative density by high pressure, resulting in effective grain size refinements and enhanced microhardness values.

Citations

Citations to this article as recorded by  
  • Analyses of Densification and Consolidation of Copper Powders during High-Pressure Torsion Process Using Finite Element Method
    Dong Jun Lee, Eun Yoo Yoon
    Journal of Korean Powder Metallurgy Institute.2015; 22(1): 6.     CrossRef
  • Microstructure Evolution and Mechanical Properties of Al-1080 Processed by a Combination of Equal Channel Angular Pressing and High Pressure Torsion
    Mohamed Ibrahim Abd El Aal, Eun Yoo Yoon, Hyoung Seop Kim
    Metallurgical and Materials Transactions A.2013; 44(6): 2581.     CrossRef
  • Trend in Research of Powder Consolidation Using Severe Plastic Deformation
    Eun Yoo Yoon, Dong Jun Lee, Dong-Hyun Ahn, Hyuk Jae Jeong, Hyoung Seop Kim
    Journal of Korean Powder Metallurgy Institute.2013; 20(2): 148.     CrossRef
  • Ultrafine Grained Cu-diamond Composites using High Pressure Torsion
    Eun-Yoo Yoon, Dong-Jun Lee, Taek-Soo Kim, Hyoung-Seop Kim
    Journal of Korean Powder Metallurgy Institute.2012; 19(3): 204.     CrossRef
  • Densification of Copper Powders using High-pressure Torsion Process
    Dong-Jun Lee, Eun-Yoo Yoon, Soo-Young Kang, Jung-Hwan Lee, Hyoung-Seop Kim
    Journal of Korean Powder Metallurgy Institute.2012; 19(5): 333.     CrossRef
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Quantitative Analysis of Roughness of Powder Surface Using Three-Dimensional Laser Profiler and its Effect on Green Strength of Powder Compacts
Dong-Jun Lee, Eun-Yoo Yoon, Ha-Neul Kim, Hee-Soo Kang, Eon-Sik Lee, Hyoung-Seop Kim
J Korean Powder Metall Inst. 2011;18(5):406-410.
DOI: https://doi.org/10.4150/KPMI.2011.18.5.406
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  • 2 Citations
AbstractAbstract PDF
Green strength is an important property of powders since high green strength guarantees easy and safe handling before sintering. The green strength of a powder compact is related to mainly mechanical and surface characters, governed by interlocking of the particles. In this study, the effect of powder surface roughness on the green strength of iron powders was investigated using a transverse rupture test. Three-dimensional laser profiler was employed for quantitative analyses of the surface roughness. Two different surface conditions, i.e. surface roughness, of powders were compared. The powders having rough surfaces show higher green strength than the round surface powders since higher roughness leads increasing interlocked area between the contacting powders.

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  • A Study on the Carbon Composite Briquette Iron Manufacturing Using Fe-containing Process Wastes
    Jong Yeong Yu, Dae Young Yang, Hee Dong Shin, Il Sohn
    Journal of the Korean Institute of Resources Recycling.2015; 24(3): 34.     CrossRef
  • Obtaining Mechanical Properties of Fe Powder Using a Combined Nanoindentation and the Finite Element Method
    Hyeok Jae Jeong, Dong Jun Lee, Eun Yoo Yoon, Eon Sik Lee, Nack Joon Kim, Hyeong Seop Kim
    Journal of Korean Powder Metallurgy Institute.2013; 20(4): 280.     CrossRef
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Effect of Particle Size on Compactibility of Water-atomized Pure Iron Powder
Dong-Jun Lee, Eun-Yoo Yoon, Ha-Neul Kim, Hee-Soo Kang, Eon-Sik Lee, Hyoung-Seop Kim
J Korean Powder Metall Inst. 2011;18(3):221-225.
DOI: https://doi.org/10.4150/KPMI.2011.18.3.221
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  • 3 Citations
AbstractAbstract PDF
In the current study, the effects of particle size on compaction behavior of water-atomized pure iron powders are investigated. The iron powders are assorted into three groups depending on the particle size; 20-45 µM, 75-106 µM, and 150-180 µM for the compaction experiments. The powder compaction procedures are processed with pressure of 200, 400, 600, and 800 MPa in a cylindrical die. After the compaction stage, the group having 150-180 µM of particle size distribution shows the best densification behavior and reaches the highest green density. The reason for these results can be explained by the largest average grain size in the largest particle group, due to the low plastic deformation resistance in large grain sized materials.

Citations

Citations to this article as recorded by  
  • Preparation of high-purity reduced iron powder by Höganäs process from ultra-pure magnetite concentrate
    Jin-tian Wu, Bin Xu, Zhong-lin Dong, Yu-juan Zhou, Liang-ping Xu, Guang-hui Li, Tao Jiang
    Journal of Central South University.2023; 30(9): 3006.     CrossRef
  • Hydrogen Reduction Behavior of Oxide Scale in Water-atomized Iron Powder
    Hea-Min Shin, Kyeong-Ho Baik
    Journal of Korean Powder Metallurgy Institute.2014; 21(6): 422.     CrossRef
  • Quantitative Analysis of Roughness of Powder Surface Using Three-Dimensional Laser Profiler and its Effect on Green Strength of Powder Compacts
    Dong-Jun Lee, Eun-Yoo Yoon, Ha-Neul Kim, Hee-Soo Kang, Eon-Sik Lee, Hyoung-Seop Kim
    Journal of Korean Powder Metallurgy Institute.2011; 18(5): 406.     CrossRef

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