Flow of linear molecules through a 4:1:4 contraction-expansion using non-equilibrium molecular dynamics: Extensional rheology and pressure drop

In this work, non-equilibrium molecular dynamics simulations are used to generate the flow of linear polymer chains (monomer-springs with FENE potential) and a Lennard-Jones fluid (Newtonian fluid) through a con traction-expansion (4:1:4) geometry. An external force field simulating a constant press...

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Detalles Bibliográficos
Autores: Castillo-Tejas, J, Rojas-Morales, A, Alvarado, JFJ, Luna-Barcenas, G, Bautista, F, Manero, O, López-Medina, F
Tipo de recurso: artículo
Estado:Versión publicada
Fecha de publicación:2009
País:México
Institución:Universidad Nacional Autónoma de México
Repositorio:Sistema de Información de la Facultad de Ciencias, UNAM
OAI Identifier:oai:repositorio.fciencias.unam.mx:11154/198
Acceso en línea:http://hdlhandlenet/123456789/230
Access Level:acceso abierto
Palabra clave:Mechanics
Non-equilibrium molecular dynamics
Extensional rheology
Pressure drop
Descripción
Sumario:In this work, non-equilibrium molecular dynamics simulations are used to generate the flow of linear polymer chains (monomer-springs with FENE potential) and a Lennard-Jones fluid (Newtonian fluid) through a con traction-expansion (4:1:4) geometry. An external force field simulating a constant pressure gradient upstream the contraction region induces the flow, where the confining action of the walls is represented by a Lennard-Jones potential. The equations of motion are solved through a multiple-step integration algorithm coupled to a Nose-Hoover dynamics [S. Nose, A unified formulation of the constant temperature molecular dynamics methods, J. Chem. Phys. 81 (1984) 511-519], i.e., to simulate a thermostat, which maintains a constant temperature, In this investigation, we assume that the energy removed by the thermostat is related to the viscous dissipation along the contraction-expansion geometry. A nonlinear increasing function between the pressure drop and the mean velocity along the contraction for the linear molecules is found, being an order of magnitude larger than that predicted for the Lennard-Jones fluid. The pressure drop of both systems (the linear molecules and Lennard-Jones fluid) is related to the dissipated energy at the contraction entry. The large deformation that the linear molecules experience and the evolution of the normal stress at the contraction entry follow a different trajectory in the relaxation process past the contraction, generating large hysteresis loops. The area enclosed by these cycles is related to the dissipated energy. Large shear stresses developed near the re-entrant corners as well as the vortex formation, dependent on the Deborah number, are also predicted at the exit of the contraction. To our knowledge, for the first time, the excessive pressure losses found in experimental contraction flows can be explained theoretically. (C) 2009 Elsevier B.V. All rights reserved.