Surface tension calculation of the Sn–Ga–In ternary alloy

Liu, Yan; Zheng, Shiyou; Ding, Guangwei; Xu, Guiyin; Qiao, Zhiyu

doi:10.1016/j.calphad.2006.09.005

Cited by 42 publications

(32 citation statements)

References 12 publications

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“…However, the choice of asymmetric constituent is not straightforward in Toop's model, and need to be adjusted by one's experience. Yan et al [33] and Qiao et al [34] have proposed a criterion of judging the asymmetric component in the ternary system, where the common component in two sub-binary systems with thermodynamic similarities should be chosen as the asymmetric component.…”

Section: Glass Forming Ranges Of Ternary Alloysmentioning

confidence: 99%

Calculation of glass forming ranges in Al–Ni–RE (Ce, La, Y) ternary alloys and their sub-binaries based on Miedema's model

Sun

Liu

et al. 2010

Journal of Alloys and Compounds

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Section: Glass Forming Ranges Of Ternary Alloysmentioning

confidence: 99%

Calculation of glass forming ranges in Al–Ni–RE (Ce, La, Y) ternary alloys and their sub-binaries based on Miedema's model

Sun

Liu

et al. 2010

Journal of Alloys and Compounds

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“…In a number of previous studies, such as [15][16][17][18][19][20][21][22][23][24][25][26][27] it was shown that the surface tension of liquid binary and ternary alloys can be successfully described by the Butler equation 28) which treats the surface as an individual thermodynamic phase being in equilibrium with the bulk.…”

Section: Butler Equationmentioning

confidence: 99%

Surface Tension of Liquid Ag–Cu Binary Alloys

et al. 2014

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Surface tension of liquid Ag-Cu binary alloys has been measured contactlessly using the technique of electromagnetic levitation in combination with the oscillating drop technique. The measurements were performed at temperatures above the melting point of alloys. The surface tension values were obtained from an analysis of the frequency spectra of droplet oscillations recorded with a CMOS-camera at 400 fps.The alloy samples covered the entire composition range. The surface tension data can be described by linear functions of temperature with negative slopes. The new experimental data were compared to the corresponding theoretical values calculated combining the Butler equation with the ideal and subregular solution models, respectively. The agreement with the experimentally obtained data is excellent for the isothermal surface tension and quite reasonable for their temperature coefficients.

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“…Recently, Yan et al [12] adopted the general solution model (GSM), originally proposed by Chou [13], to predict the surface tension of ternary systems based on the limiting binaries data. In this model, the excess surface tension Ex of a ternary alloy is calculated according to Eq.…”

Section: Surface Tension: Experiments and Modelmentioning

confidence: 99%

Surface tension and density of liquid Sn–Ag–Cu alloys

Fima

2012

International Journal of Materials Research

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Surface tension and density of liquid Sn-Ag-Cu alloysThe surface tension and density of Sn -Ag -Cu alloys, lying along two cross-sections of silver to copper molar ratios equal to 1 and 7/3, were studied. Sessile drop measurements were carried out over a broad temperature range. It was found that both surface tension and density decrease with increasing concentration of Sn. With the increase in temperature, the density decreases linearly for all compositions, whereas the surface tension shows linear and curvilinear dependence for different compositions. The results are compared with literature data obtained with a different technique and the results of model calculations. Relatively good agreement is observed between the models and experimental data.

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Surface tension calculation of the Sn–Ga–In ternary alloy

Cited by 42 publications

References 12 publications

Calculation of glass forming ranges in Al–Ni–RE (Ce, La, Y) ternary alloys and their sub-binaries based on Miedema's model

Calculation of glass forming ranges in Al–Ni–RE (Ce, La, Y) ternary alloys and their sub-binaries based on Miedema's model

Surface Tension of Liquid Ag–Cu Binary Alloys

Surface tension and density of liquid Sn–Ag–Cu alloys

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