Separating Technology of Pure Zirconia from Zircon-Sand by the Ar-H2 Arc Plasma Fusion and the Microwave Leaching

Jeong Han Lee; Da Som Kang; Min Kuk Moon; Sung Kil Hong

doi:10.4028/www.scientific.net/MSF.879.1080

Paper Titles

Welding of Automotive Aluminum Alloys by Laser Wobbling Processing
p.1057

Mechanical Properties of Polymer-Based Hybrid Films: Tailoring the Hybrid Interface Using Soft Chemistry
p.1063

Mechanical Behavior of a Metal Matrix Nanocomposite Synthesized by High-Pressure Torsion via Diffusion Bonding
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Effect of CH₄ Content on the Characteristics of Surface Layers of Low Temperature Plasma Nitrided 2205 Duplex Stainless Steel
p.1074

Separating Technology of Pure Zirconia from Zircon-Sand by the Ar-H₂ Arc Plasma Fusion and the Microwave Leaching
p.1080

Atomic Layer Deposited Protective Layers
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The Role of Preliminary Heat Treatment in the Formation of Ultrafine-Grained Structure in the Implementation of the Combined Process "Rolling - Equal Channel Angular Pressing"
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The Study of the Microstructure of the Metal after Rolling Thick Workpieces of Nonferrous Metals and Alloys in Relief and Smooth Rolls
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Gas Nitriding of High-Vanadium Alloy Steel
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HomeMaterials Science ForumMaterials Science Forum Vol. 879Separating Technology of Pure Zirconia from...

Separating Technology of Pure Zirconia from Zircon-Sand by the Ar-H₂ Arc Plasma Fusion and the Microwave Leaching

Abstract:

Zirconia (ZrO₂) has excellent properties such as high toughness, high strength, thermal stability and high corrosion resistance. Thus, recent zirconia has been spotlighted as a dental material. Most of pure zirconia has been separated from zircon sand (ZrSiO₄) by wet refining process which is very complex and not an environmental. The arc plasma fusion method has the advantages as a sustainable process that can easily and quickly get very good fine and high pure powders from the original materials compared with traditional wet method. In this study, zircon sand is separated into zirconia and silica by using the Ar-H₂(hydrogen) arc plasma refining. And then silica is removed from it by the microwave leaching method to produce a high pure zirconia. Argon gas, hydrogen gas, copper anode and tungsten cathode are used for the plasma arc generation. To facilitate zirconia and silica separation, carbon of 1-3molar ratios are added with zircon sand. Plasma melting were sequentially conducted two processes. After a reduction process using Ar gas only, it was refined using a mixed gas of Ar-H₂. After melting and water cooling in chamber, the solid phases composed with zirconia and silica were obtained at 240 ̊C, and 20% sulfuric acid solution was used as the leaching materials to obtain a high purity zirconia (more than 99%).

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Materials Science Forum (Volume 879)

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1080-1085

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.879.1080

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Online since:

November 2016

Authors:

Jeong Han Lee, Da Som Kang, Min Kuk Moon, Sung Kil Hong*

Keywords:

Ar-H₂ Plasma Arc Melting, High Purity, Microwave Leaching, Zirconia, Zircon-Sand

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