Numerical Model for Interfacial Reaction between Titanium and Zirconia in Electromagnetic Field

Ai Hui Liu; Yan Wei Sui

doi:10.4028/www.scientific.net/AMR.716.10

Paper Titles

Aluminum Oxide Nanoparticles Upregulate ED1 Expression in Rat Olfactory Bulbs by Repeated Intranasal Instillation
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Numerical Model for Interfacial Reaction between Titanium and Zirconia in Electromagnetic Field
p.10

Experimental Correlation for the Effect of Metallurgical Parameters on the Hardness of 356 and 319 Aluminum Alloys Using Minitab Software
p.15

Effects of Aspect Ratio of Carbon Nanotubes on Crystallization Behavior of Polylactide Composites
p.25

Research on Preparation Technique of C100 Ultra-High Performance Self-Compaction Concrete
p.30

The Synthesis of 2-Oxo-1-Pyrrole Alkyl Propionitrile
p.36

Electrochromicproperties of Vanadium Oxide Thin Film Deposited by Magnetron Sputtering
p.40

Photocatalytic Decomposition of Gaseous HCHO by N-Zr-TiO₂ Catalysts
p.44

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Numerical Model for Interfacial Reaction between Titanium and Zirconia in Electromagnetic Field

Abstract:

Based on the interfacial reaction model between Ti and ZrO₂ in gravity field, taking account of the effect of electromagnetic field, a comprehensive numerical model for simulation of heat and mass transfer is established to study the interfacial reaction between liquid Ti and ZrO₂ in electromagnetic field. With the proposed model, numerical simulations are preformed to investigate the influences of pouring temperature, holding time on the oxygen concentration and reactive layer thickness in metal. The results show that both the oxygen concentration and the thickness of reactive layer in metal increase with increasing the holding time and the pouring temperature. The thickness of reactive layer in electromagnetic field is greater than that in gravity field.