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Ejima, Tatsuhiko; Shimakage, Kazuyoshi; Sato, Yuzuru; Okuda, Haruji; Kumada, Nobuhiro; Ishigaki, Akio

doi:10.1246/nikkashi.1982.961

Cited by 15 publications

(7 citation statements)

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“…Fig. 8 shows the variation of the viscosity of LiCl-CsCl mixtures at 973 K as a function of the melt composition [21,22].…”

Section: Influence On the Chemical Stability Of Uranium Complexes By mentioning

confidence: 99%

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Electrochemical behavior and electronic absorption spectra of uranium trivalent ions in molten LiCl–CsCl mixtures

Nagai

Uehara

Fujii

et al. 2011

Journal of Nuclear Materials

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“…Fig. 8 shows the variation of the viscosity of LiCl-CsCl mixtures at 973 K as a function of the melt composition [21,22].…”

Section: Influence On the Chemical Stability Of Uranium Complexes By mentioning

confidence: 99%

“…of CsCl in melt viscosity at 973 K (mPa s) Relation of viscosity at 973 K[21,22] to mole fraction of CsCl in LiCl-CsCl mixtures. Relation of E°0(U 3+ |U) in LiCl-CsCl mixtures at 973 K to viscosity[21,22] of melts.…”

mentioning

confidence: 99%

Electrochemical behavior and electronic absorption spectra of uranium trivalent ions in molten LiCl–CsCl mixtures

Nagai

Uehara

Fujii

et al. 2011

Journal of Nuclear Materials

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“…Abe et al (1980), oscillating cup method +7.85 (1 168.6 K) T. Ejima et al (1985), oscsillating cup method +2.47 (1 168.6 K) T. Ito et al (1989). oscillating cup method +3.15 (1168.8 K) E.H. Ballouki et al (1989), capillary method +10.52 (1221.9 K) T. Ejima et al (1982). capillary method 4 .…”

Section: Resultsmentioning

confidence: 99%

“…x E. H. Ballouki et al (1987) capillary method IS]; -T. Ejima et al (1982) capillary method [13]; 0 R. Galasiu (1993) capillary method [14]; 0 S. Zuca et al (1976) oscillating cup method [I71 become larger at higher temperature which suggests the need for a most rigorous control to this parameter. The large discrepancy between viscosities determined by the so-called "outflow method" [5] proves that the method does not ensure acceptable error limits and, secondly, that adopting nonconventional methods in studies of molten salt viscosity requires a careful analysis of error sources.…”

Section: Resultsmentioning

confidence: 99%

Viscosity Measurements on Molten Salts with an Oscillating Cup Viscometer: Viscosity of Molten KNO₃ and NaCl

Tolbaru

Borcan

Zuca

1998

Ber Bunsenges Phys Chem

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An oscillating cup viscometer interfaced to an automatic data acquisition and processing system (computer, interface, software) was built for viscosity measurements in molten salts below 1400 K.In order to avoid the "meniscus effect", the main source of errors of the method, the measurements were carried out in the so-called "full cup" condition, i.e. with the height of the liquid column (h) of 11.2 cm, the overall height of the cup being 11.9 cm. An adequate software supplied values at each temperature, as function of R, I, 6, h, p and T values in air and with liquid containing cup. The viscosity of molten KNO3 and NaCI, both of "standard salt purity", was reinvestigated over a temperature range of 100 K above their melting points. The standard deviation of the data obtained was +0.38%. These data were systematically lower (3% for qNacl and 2% for q K N~, ) than those obtained earlier by the same method, but agree within +0.9% with the recommended Janz's "calibration quality viscosity data".One can conclude that the method gives accurate results only if operated in "full cup" condition.

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“…As the viscosity is the resistance against shear stress in an assumed liquid layer, the viscosity of molten salt may be a measure of ionic interaction and the liquid structure. The authors have developed a capillary viscometer and an oscillating viscometer as shown in Figures 12 and 13 (22)(23)(24)(25)(26). The capillary viscometer made of quartz was used in combination with transparent "Gold furnace" like in the capillary rise surface tension cell up to 1200K.…”

Section: Viscositymentioning

confidence: 99%

(Invited) Physical Properties of High Temperature Molten Salts

Sato

2010

ECS Trans.

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High temperature molten salts are very important in the industrial field such as active metal production. In any cases including the use as the electrolyte, the physical properties, for example, density, electrical conductivity, viscosity are essentially important. On the other hand, molten salts consist of ions and are agglutinated by the coulombic interaction. The ionicity of the molten salts is affected by the strength of coulombic force of the constituent ionic species. Too strong coulombic force makes the salts non ionic, for example, SiCl4, and prevents the formation of stable ionic molten salts. Therefore, the phenomena of complex formation are important to consider the properties of molten salts. The author studied various physical properties of many molten salts. In this paper, the physical properties are described related to the ionic constitution including complex formation in the molten salts.

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Cited by 15 publications

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Electrochemical behavior and electronic absorption spectra of uranium trivalent ions in molten LiCl–CsCl mixtures

Electrochemical behavior and electronic absorption spectra of uranium trivalent ions in molten LiCl–CsCl mixtures

Viscosity Measurements on Molten Salts with an Oscillating Cup Viscometer: Viscosity of Molten KNO₃ and NaCl

(Invited) Physical Properties of High Temperature Molten Salts

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Cited by 15 publications

References 0 publications

Electrochemical behavior and electronic absorption spectra of uranium trivalent ions in molten LiCl–CsCl mixtures

Electrochemical behavior and electronic absorption spectra of uranium trivalent ions in molten LiCl–CsCl mixtures

Viscosity Measurements on Molten Salts with an Oscillating Cup Viscometer: Viscosity of Molten KNO3 and NaCl

(Invited) Physical Properties of High Temperature Molten Salts

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Viscosity Measurements on Molten Salts with an Oscillating Cup Viscometer: Viscosity of Molten KNO₃ and NaCl