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Assael, Marc J.; Dalaouti, N. K.

doi:10.1023/a:1010759629398

Cited by 16 publications

(7 citation statements)

References 7 publications

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“…15 in comparison with experimental data [68][69][70] and various correlations from the literature [52,57,58,67]. The experimental data and the correlations agree within 10% and there is a remarkable agreement with the present simulation results, especially for temperatures below 325 K. Note that the statistical uncertainties of the present simulation results are about 5%.…”

Section: Cyclopentanesupporting

confidence: 86%

Lennard-Jones force field parameters for cyclic alkanes from cyclopropane to cyclohexane

Muñoz-Muñoz

Guevara‐Carrion

Llano‐Restrepo

et al. 2015

Fluid Phase Equilibria

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Section: Cyclopentanesupporting

confidence: 86%

Lennard-Jones force field parameters for cyclic alkanes from cyclopropane to cyclohexane

Muñoz-Muñoz

Guevara‐Carrion

Llano‐Restrepo

et al. 2015

Fluid Phase Equilibria

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“…From the aforementioned sets, 25 were considered as primary data. The data of Sun et al, 12 Watanabe and Seong, 13 Watanabe, 17 Assael and Dalaouti, 14 Assael et al, 20 Perkins et al, 15,21 Lei et al, 16 Ramires et al, 18,22 Yamada et al, 19 Taxis et al, 23 Charitidou et al, 24 Nieto de Castro et al, 26 and Nagasaka and Nagashima, 28 were all performed in transient hot-wire instruments in an absolute way, exhibited very low uncertainty (typically 60.5%), and fulfill the aforementioned criteria for primary data. The data of Wu et al 10,11 and Kashiwagi et al, 27 performed also in transient hot-wire instruments but of slightly higher uncertainty, were also included in the primary data sets.…”

Section: Methodsmentioning

confidence: 97%

Reference Correlation of the Thermal Conductivity of Toluene from the Triple Point to 1000 K and up to 1000 MPa

Assael

Mylona

Huber

et al. 2012

Journal of Physical and Chemical Reference Data

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This paper contains new, representative equations for the thermal conductivity of toluene. The equations are based in part upon a body of experimental data that has been critically assessed for internal consistency and for agreement with theory whenever possible. Although there are a sufficiently large number of data at normal temperatures, data at very low and very high temperatures as well as near the critical region are scarce. In the case of the dilute-gas thermal conductivity, a theoretically based correlation was adopted in order to extend the temperature range of the experimental data. Moreover, in the critical region, the experimentally observed enhancement of the thermal conductivity is well represented by theoretically based equations containing just one adjustable parameter. The correlations are applicable for the temperature range from the triple point to 1000 K and pressures up to 1000 MPa. The overall uncertainty (considered to be estimates of a combined expanded uncertainty with a coverage factor of two) of the proposed correlation is estimated, for pressures less than 700 MPa and temperatures less than 550 K, to be less than 3% for the liquid, while for the region 550 K ≤ T ≤ 700 K the uncertainty is estimated to be 4%. For the region T > 700 K and 500 MPa ≤ p ≤ 1000 MPa, the equations can safely be used with an uncertainty of the order of 10%. Finally, the uncertainty along the saturation line is estimated to be 2% with a coverage factor of two.

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“…In the 1930s the hot-wire technique was used to measure the thermal conductivity of porous materials . Then it was used to measure the thermal conductivity of fluids. − This method puts a metal wire sensor in the sample vessel filled with the fluid sample and uses a power supply to generate an electric current in the wire. According to the Joule’s law, the electrical current induces heat inside the metal wire.…”

Section: Viscosity and Thermal Conductivitymentioning

confidence: 99%

A Review of Experimental Researches on the Thermophysical Properties of Hydrogen-Containing Mixtures at High Temperatures and High Pressures

Cheng

Shang

et al. 2021

J. Chem. Eng. Data

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Hydrogen is a promising energy carrier compared with the direct burning of coal or oil. The gasification processes of coal, oil, and other organic substances in supercritical water (>647 K and 22.1 MPa) produce hydrogen-containing mixtures. The mixtures mainly contain H2, CO2, CH4, and CO. Knowledge of the thermophysical properties which mainly include the PVT property, viscosity, and thermal conductivity is significant for the design and optimization of the relevant equipment. Currently available experimental researches on the thermophysical properties of hydrogen-containing mixtures at high temperatures and high pressures are reviewed. The review describes the progress in developing the measurement apparatuses, obtaining the thermophysical data, and observing the abnormal phenomena for the PVT property, viscosity, and thermal conductivity along with proposing the equation of state and transport property correlations of hydrogen-containing mixtures at high temperatures and high pressures. In addition, the possible advancements in both experiment and theory in the future are discussed.

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Cited by 16 publications

References 7 publications

Lennard-Jones force field parameters for cyclic alkanes from cyclopropane to cyclohexane

Lennard-Jones force field parameters for cyclic alkanes from cyclopropane to cyclohexane

Reference Correlation of the Thermal Conductivity of Toluene from the Triple Point to 1000 K and up to 1000 MPa

A Review of Experimental Researches on the Thermophysical Properties of Hydrogen-Containing Mixtures at High Temperatures and High Pressures

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