2010
DOI: 10.1007/s11663-010-9456-3
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Theoretical Calculations of the Surface Tension of Liquid Transition Metals

Abstract: The surface tension of pure liquid mercury in the temperature range 273 K to 523 K (0°C to 250 C°) was calculated using our previously reported equation. The results were compared with the experimental data and showed a good agreement. The surface tension of mercury decreases linearly with temperature, confirming a negative slope, and therefore shows the usual linear temperature dependence. The calculated surface excess entropy (0.21) is in excellent consistence with the experimental value (0.22). The surface … Show more

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Cited by 21 publications
(9 citation statements)
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“…Transmitting and receiving antennas were placed a distance of 1.45 cm apart, and the polarizer device placed directly between them ( 0.7 ≈ cm from each antenna). The antennas measure 27.6 mm in the direction of the E-field and 22.8 mm in the H-plane (629.28 mm 2 ), whereas the active area of the polarizer measures 1760 mm 2 . Signal amplitude values were obtained using an IFR AN930 spectrum analyzer.…”
Section: Polarizer Device Demonstrationmentioning
confidence: 99%
“…Transmitting and receiving antennas were placed a distance of 1.45 cm apart, and the polarizer device placed directly between them ( 0.7 ≈ cm from each antenna). The antennas measure 27.6 mm in the direction of the E-field and 22.8 mm in the H-plane (629.28 mm 2 ), whereas the active area of the polarizer measures 1760 mm 2 . Signal amplitude values were obtained using an IFR AN930 spectrum analyzer.…”
Section: Polarizer Device Demonstrationmentioning
confidence: 99%
“…(1) was, previously, applied for calculating the surface tension of pure liquid metals such as gallium [24], bismuth [26] and mercury [27], in the frame work of Eyring statistical thermodynamic theory [28,29]:…”
Section: Theorymentioning
confidence: 99%
“…The model for the calculation of the surface tension of pure liquid metals [24,26,27] is extended to be valid for binary liquid alloys [25]. The necessary model equations for calculating the surface tension of a liquid binary alloy are presented as follows:…”
Section: Theorymentioning
confidence: 99%
“…Recently, an equation was derived for calculating the surface tension of pure liquid metals [15][16][17]. This equation may be applied for surface tension calculations of a nonmetal and a metalloid such as molten silicon and germanium.…”
Section: Theory and Modelmentioning
confidence: 99%
“…In extension to the earlier work [15][16][17], this paper presents a theoretical calculation of the temperature dependence surface tension of molten silicon (1687-1825 K) and germanium (1211-1400 K). The model-calculated results showed reasonable consistency with the reported experiment measured.…”
Section: Introductionmentioning
confidence: 97%