Finite element simulation of dynamic wetting flows as an interface formation process

Handle URI:
http://hdl.handle.net/10754/598329
Title:
Finite element simulation of dynamic wetting flows as an interface formation process
Authors:
Sprittles, J.E.; Shikhmurzaev, Y.D.
Abstract:
A mathematically challenging model of dynamic wetting as a process of interface formation has been, for the first time, fully incorporated into a numerical code based on the finite element method and applied, as a test case, to the problem of capillary rise. The motivation for this work comes from the fact that, as discovered experimentally more than a decade ago, the key variable in dynamic wetting flows - the dynamic contact angle - depends not just on the velocity of the three-phase contact line but on the entire flow field/geometry. Hence, to describe this effect, it becomes necessary to use the mathematical model that has this dependence as its integral part. A new physical effect, termed the 'hydrodynamic resist to dynamic wetting', is discovered where the influence of the capillary's radius on the dynamic contact angle, and hence on the global flow, is computed. The capabilities of the numerical framework are then demonstrated by comparing the results to experiments on the unsteady capillary rise, where excellent agreement is obtained. Practical recommendations on the spatial resolution required by the numerical scheme for a given set of non-dimensional similarity parameters are provided, and a comparison to asymptotic results available in limiting cases confirms that the code is converging to the correct solution. The appendix gives a user-friendly step-by-step guide specifying the entire implementation and allowing the reader to easily reproduce all presented results, including the benchmark calculations. © 2012 Elsevier Inc.
Citation:
Sprittles JE, Shikhmurzaev YD (2013) Finite element simulation of dynamic wetting flows as an interface formation process. Journal of Computational Physics 233: 34–65. Available: http://dx.doi.org/10.1016/j.jcp.2012.07.018.
Publisher:
Elsevier BV
Journal:
Journal of Computational Physics
KAUST Grant Number:
KUK-C1-013-04
Issue Date:
Jan-2013
DOI:
10.1016/j.jcp.2012.07.018
Type:
Article
ISSN:
0021-9991
Sponsors:
The authors would like to thank Dr Mark Wilson, Dr Paul Suckling and Dr Alex Lukyanov for many stimulating discussions about the FEM implementation of dynamic wetting phenomena and Jonathan Simmons for carefully proof reading the manuscript. JES kindly acknowledges the financial support of EPSRC via a Postdoctoral Fellowship in Mathematics.This publication was based on work supported in part by Award No KUK-C1-013-04, made by King Abdullah University of Science and Technology (KAUST).
Appears in Collections:
Publications Acknowledging KAUST Support

Full metadata record

DC FieldValue Language
dc.contributor.authorSprittles, J.E.en
dc.contributor.authorShikhmurzaev, Y.D.en
dc.date.accessioned2016-02-25T13:18:49Zen
dc.date.available2016-02-25T13:18:49Zen
dc.date.issued2013-01en
dc.identifier.citationSprittles JE, Shikhmurzaev YD (2013) Finite element simulation of dynamic wetting flows as an interface formation process. Journal of Computational Physics 233: 34–65. Available: http://dx.doi.org/10.1016/j.jcp.2012.07.018.en
dc.identifier.issn0021-9991en
dc.identifier.doi10.1016/j.jcp.2012.07.018en
dc.identifier.urihttp://hdl.handle.net/10754/598329en
dc.description.abstractA mathematically challenging model of dynamic wetting as a process of interface formation has been, for the first time, fully incorporated into a numerical code based on the finite element method and applied, as a test case, to the problem of capillary rise. The motivation for this work comes from the fact that, as discovered experimentally more than a decade ago, the key variable in dynamic wetting flows - the dynamic contact angle - depends not just on the velocity of the three-phase contact line but on the entire flow field/geometry. Hence, to describe this effect, it becomes necessary to use the mathematical model that has this dependence as its integral part. A new physical effect, termed the 'hydrodynamic resist to dynamic wetting', is discovered where the influence of the capillary's radius on the dynamic contact angle, and hence on the global flow, is computed. The capabilities of the numerical framework are then demonstrated by comparing the results to experiments on the unsteady capillary rise, where excellent agreement is obtained. Practical recommendations on the spatial resolution required by the numerical scheme for a given set of non-dimensional similarity parameters are provided, and a comparison to asymptotic results available in limiting cases confirms that the code is converging to the correct solution. The appendix gives a user-friendly step-by-step guide specifying the entire implementation and allowing the reader to easily reproduce all presented results, including the benchmark calculations. © 2012 Elsevier Inc.en
dc.description.sponsorshipThe authors would like to thank Dr Mark Wilson, Dr Paul Suckling and Dr Alex Lukyanov for many stimulating discussions about the FEM implementation of dynamic wetting phenomena and Jonathan Simmons for carefully proof reading the manuscript. JES kindly acknowledges the financial support of EPSRC via a Postdoctoral Fellowship in Mathematics.This publication was based on work supported in part by Award No KUK-C1-013-04, made by King Abdullah University of Science and Technology (KAUST).en
dc.publisherElsevier BVen
dc.subjectCapillary riseen
dc.subjectComputationen
dc.subjectDynamic wettingen
dc.subjectFluid mechanicsen
dc.subjectInterface formationen
dc.subjectShikhmurzaev modelen
dc.titleFinite element simulation of dynamic wetting flows as an interface formation processen
dc.typeArticleen
dc.identifier.journalJournal of Computational Physicsen
dc.contributor.institutionUniversity of Oxford, Oxford, United Kingdomen
dc.contributor.institutionUniversity of Birmingham, Birmingham, United Kingdomen
kaust.grant.numberKUK-C1-013-04en
All Items in KAUST are protected by copyright, with all rights reserved, unless otherwise indicated.