Dynamics of a thin film flowing down a heated wall with finite thermal diffusivity

Dallaston, Michael C.; Tseluiko, Dmitri; Kalliadasis, Serafim

doi:10.1103/physrevfluids.1.073903

Cited by 6 publications

(3 citation statements)

References 54 publications

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“…In our analysis we have assumed throughout that the temperature at the wall is exactly specified. However, in physical implementation it is more likely that the boundary condition would involve either a specification of the heat flux or some linear combination of temperature and heat flux (conceivably coupled to another thermal problem within the wall such as considered by Dallaston, Tseluiko & Kalliadasis (2016)). Our modelling methodology can be easily extended to these more general boundary conditions (see appendix A).…”

Section: Resultsmentioning

confidence: 99%

Robust low-dimensional modelling of falling liquid films subject to variable wall heating

et al. 2019

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Accurate low-dimensional models for the dynamics of falling liquid films subject to localized or time-varying heating are essential for applications that involve patterning or control. However, existing modelling methodologies either fail to respect fundamental thermodynamic properties or else do not accurately capture the effects of advection and diffusion on the temperature profile. We argue that the best-performing long-wave models are those that give the surface temperature implicitly as the solution of an evolution equation in which the wall temperature alone (and none of its derivatives) appears as a source term. We show that, for both flat and non-uniform films, such a model can be rationally derived by expanding the temperature field about its free-surface values. We test this model in linear and nonlinear regimes, and show that its predictions are in remarkable quantitative agreement with full Navier–Stokes calculations regarding the surface temperature, the internal temperature field and the surface displacement that would result from temperature-induced Marangoni stresses.

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Section: Resultsmentioning

confidence: 99%

Robust low-dimensional modelling of falling liquid films subject to variable wall heating

et al. 2019

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“…Novel extensions in the present study compared with that work are the computation of asymmetric similarity solutions (which are stable in some parameter regimes and, therefore, of interest), and the use of continuation to compute periodic orbits in the scaled time and space coordinate system in which a similarity solution corresponds to a steady state. While Dallaston et al (2018) is an instance of numerical continuation being used to compute the stability of similarity solutions, the use of numerical continuation to compute the stability of steady states has previously been applied in thin film models in Thiele & Knobloch (2003 and to the Orr-Sommerfeld equations of interfacial hydrodynamic models in Dallaston, Tseluiko & Kalliadasis (2016). In addition, the tracing of periodic solution branches via continuation has been applied previously in Lin et al (2016), although in unscaled time and space.…”

Section: Introductionmentioning

confidence: 99%

Regular and complex singularities of the generalized thin film equation in two dimensions

et al. 2021

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“…Atomic force microscopy in a tapping mode was successfully used for the characterization of the thin-film profile at about 1 nm away from the contact line, , but it is insufficient to further understand how the thin-film profile varies with time. In fact, the thin-film evolution is critical for understanding the thin-film dynamics. − …”

Section: Introductionmentioning

confidence: 99%

Fluid Flow and Thin-Film Evolution near the Triple Line during Droplet Evaporation of Self-Rewetting Fluids

Yang

Zhou

et al. 2018

Langmuir

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The microscopic region near the triple line plays an important role in the heat and mass transfer of droplets, although the mechanisms of evaporation and internal flow remain unclear. This paper describes an experimental study of fluid flow and thin-film evolution near the triple line in sessile droplets of self-rewetting fluids, aqueous solutions of alcohols with the number of carbon atoms varying from 1 to 7, to analyze the influence of various factors on the mesoscale flows. The mechanism of internal flow for self-rewetting fluid droplets was different from that of conventional fluids, and hence, a novel expression of the in-plane average velocity was fitted for them. The temporal and spatial evolution of the thin-film thickness near the triple line during droplet evaporation was obtained by using a proposed subregion method, which was developed from an evanescent-wave-based multilayer nanoparticle image velocimetry technique. The self-rewetting fluids are conducive to increase the microscopic critical contact angle and the energy barrier of the contact line, which reduces the rate of thin-film thickness variation. The inhibited impact of self-rewetting fluids on evaporation increases gradually with an increasing number of carbon atoms.

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Dynamics of a thin film flowing down a heated wall with finite thermal diffusivity

Cited by 6 publications

References 54 publications

Robust low-dimensional modelling of falling liquid films subject to variable wall heating

Robust low-dimensional modelling of falling liquid films subject to variable wall heating

Regular and complex singularities of the generalized thin film equation in two dimensions

Fluid Flow and Thin-Film Evolution near the Triple Line during Droplet Evaporation of Self-Rewetting Fluids

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