Influence of Li2O on the Viscous Behavior of CaO–Al2O3–12 mass% Na2O–12 mass% CaF2 Based Slags

The viscous behavior of the CaO–Al2O3–12 mass%Na2O–12 mass%CaF2 based slag system with various concentrations of Li2O has been studied using the rotating spindle method to understand the effects on the viscosity with these additives. Li2O additions up to 1 mass% significantly lowered the viscosity b...

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Bibliographic Details
Published inISIJ International Vol. 52; no. 1; pp. 68 - 73
Main Authors Kim, Gi Hyun, Sohn, Il
Format Journal Article
LanguageEnglish
Published Tokyo The Iron and Steel Institute of Japan 2012
Iron and Steel Institute of Japan
Subjects
[AlO4]-tetrahedral network
activation energy
Al–O stretching
Applied sciences
depolymerization
Exact sciences and technology
FTIR
Li2O
Metals. Metallurgy
viscosity
XPS
Drawing
Viscosity
tetrahedral network
AIO
Al―O stretching
Forming
Activation
O
depolymerization
FTIR
Slag
Photoelectron spectrometry
XPS
Alumina
Activation energy
Li
Calcium fluoride
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Summary:The viscous behavior of the CaO–Al2O3–12 mass%Na2O–12 mass%CaF2 based slag system with various concentrations of Li2O has been studied using the rotating spindle method to understand the effects on the viscosity with these additives. Li2O additions up to 1 mass% significantly lowered the viscosity by breaking the [AlO4]-tetrahedral network structure of molten fluxes, but Li2O concentrations above this level was comparatively less effective in lowering the viscosity. The viscosity was lower at higher temperatures and from an Arrhenius relationship, the activation energy was calculated to be between approximately 180 to 190 kJ/mol. Fourier Transform Infra-Red (FTIR) analysis of as-quenched slag samples showed the characteristic Al–O stretching vibration in the wavenumber of 800 cm–1 and 660 cm–1. Slags with higher viscosity showed a slightly wider trough near the 800 cm–1 and 660 cm–1 Al–O stretching bands. XPS analysis of slags with various concentrations of Li2O indicated the fraction of bridged oxygen (Oo) decreased and the non-bridged oxygen (O–) increased with higher concentrations of Li2O. Li2O additions up to 1 mass% significantly decreased the bridged oxygen fraction, which seem to correlate well with the viscosity measurements.
ISSN:0915-1559
1347-5460
DOI:10.2355/isijinternational.52.68