Integral relations, a simplified method to find interfacial resistivities for heat and mass transfer |
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Authors: | Jialin Ge JM Simon S Kjelstrup |
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Institution: | Department of Chemistry, Norwegian University of Science and Technology, 7491 Trondheim, Norway |
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Abstract: | Integral relations were used to predict interface film transfer coefficients for evaporation and condensation. According to these, all coefficients can be calculated for one-component systems, using the thermal resistivity and the enthalpy profile through the interface. The expressions were verified in earlier work using non-equilibrium molecular dynamics simulations for argon-like particles, which interacted with a short-range Lennard-Jones (LJ) spline potential, which becomes zero at about 1.7 times the LJ-diameter. In this paper we verify the validity of these relations for a long-range LJ spline potential which becomes zero at 2.5 times the diameter. In an earlier paper we have documented for this system that in particular the absolute heat of transfer becomes much larger than the value predicted by kinetic theory. This was not the case for the short-range potential. The findings are important for modelling of one-component phase transitions. |
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Keywords: | Argon Vapor-liquid interface Non-equilibrium molecular dynamics Heat of transport Interface film resistivities Integral relations Range of the potential |
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