On the breakup of fluid films of finite and infinite extent

Diez, Javier A.; Kondic, Lou

doi:10.1063/1.2749515

Cited by 79 publications

(152 citation statements)

References 70 publications

(101 reference statements)

Supporting

Mentioning

144

Contrasting

Unclassified

Order By: Relevance

“…Above a critical translation speed, however, a thin liquid film is left on the wafer, that spontaneously breaks up, dewets and leads to undesirable residual droplets on the substrate. Similar film rupture and dewetting phenomena have been described for thin layers of polymer melts [18][19][20][21][22][23][24][25][26][27], metals [28][29][30][31][32] and oil films submersed in water [33][34][35].…”

Section: Introductionsupporting

confidence: 65%

Deformation and dewetting of thin liquid films induced by moving gas jets

Berendsen

Zeegers

Darhuber

2013

Journal of Colloid and Interface Science

View full text Add to dashboard Cite

Section: Introductionsupporting

confidence: 65%

Deformation and dewetting of thin liquid films induced by moving gas jets

Berendsen

Zeegers

Darhuber

2013

Journal of Colloid and Interface Science

View full text Add to dashboard Cite

“…Note that here we are assuming a dependence on θ eq in the form of (tan 2 θ eq )/2 instead of (1 − cos θ eq ) as usually seen in the literature. 24,30 In fact, the former dependence comes directly from using the linearized form of the free surface curvature, 31 which is consistent with the hypothesis of small slope in the L-W approximation, while the latter is derived when using the complete (nonlinear) form. The connection between K and θ eq has been recently discussed in more detail in Ref.…”

Section: A Long-wave Modelsupporting

confidence: 70%

“…29 Instead of characterizing the interaction by means of A, it is also possible to relate K with the equilibrium contact angle, θ eq , as discussed in some detail in, e.g., Ref. 24. Briefly, through the "augmented" Young-Laplace condition, which assumes a local equilibrium of pressures, one obtains K = tan 2 (θ eq )/(2Mh * ), where M = (n − m)/((m − 1)(n − 1)); we use (n, m) = (3, 2), and h * = 10 −3 except if specified differently.…”

Section: A Long-wave Modelmentioning

confidence: 99%

“…We continue by describing the L-W model which also uses the slip model for consistency with the VoF based solver, and specifies the contact angle via a disjoining pressure approach, discussed in some detail in, e.g., Ref. 24. In Sec.…”

Section: Introductionmentioning

confidence: 99%

“…24 and the references therein). Using the time and length scales defined previously, the resulting (nondimensional) equation for the fluid thickness, h = h(x, y, t), …”

Section: A Long-wave Modelmentioning

confidence: 99%

See 2 more Smart Citations

Comparison of Navier-Stokes simulations with long-wave theory: Study of wetting and dewetting

et al. 2013

View full text Add to dashboard Cite

The classical long-wave theory (also known as lubrication approximation) applied to fluid spreading or retracting on a solid substrate is derived under a set of assumptions, typically including small slopes and negligible inertial effects. In this work, we compare the results obtained by using the long-wave model and by simulating directly the full two-phase Navier-Stokes equations employing a volume-of-fluid method. In order to isolate the influence of the small slope assumption inherent in the longwave theory, we present a quantitative comparison between the two methods in the regime where inertial effects and the influence of gas phase are negligible. The flow geometries that we consider include wetting and dewetting drops within a broad range of equilibrium contact angles in planar and axisymmetric geometries, as well as liquid rings. For perfectly wetting spreading drops we find good quantitative agreement between the models, with both of them following rather closely Tanner's law. For partially wetting drops, while in general we find good agreement between the two models for small equilibrium contact angles, we also uncover differences which are particularly evident in the initial stages of evolution, for retracting drops, and when additional azimuthal curvature is considered. The contracting rings are also found to evolve differently for the two models, with the main difference being that the evolution occurs on the faster time scale when the long-wave model is considered, although the ring shapes are very similar between the two models. C 2013 AIP Publishing LLC. [http://dx

show abstract

Breakup of finite fluid films

Kondic

Diez

2007

Proc Appl Math and Mech

View full text Add to dashboard Cite

We study the dewetting process of thin fluid films that partially wet a solid surface. Using long wave (lubrication) approximation, we formulate a nonlinear partial differential equation governing the evolution of the film thickness, h. This equation includes the effects of capillarity, gravity, and additional conjoining/disjoining pressure term to account for intermolecular forces. We perform standard linear stability analysis of an infinite flat film, and identify the corresponding stable, unstable and metastable regions. Within this framework, we analyze the evolution of a semi-infinite film of length L in one direction. The numerical simulations show that for long and thin films, the dewetting fronts of the film generate a pearling process involving successive formation of ridges at the film ends and consecutive pinch-off behind these ridges. On the other hand, for shorter and thicker films, the evolution ends up by forming a single drop. The time evolution as well as the final drops pattern shows a competition between the dewetting mechanisms caused by nucleation and by free surface instability.

show abstract

On the breakup of fluid films of finite and infinite extent

Cited by 79 publications

References 70 publications

Deformation and dewetting of thin liquid films induced by moving gas jets

Deformation and dewetting of thin liquid films induced by moving gas jets

Comparison of Navier-Stokes simulations with long-wave theory: Study of wetting and dewetting

Breakup of finite fluid films

Contact Info

Product

Resources

About