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Paradoxes in Capillary Flows James Sprittles Yulii Shikhmurzaev.

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1 Paradoxes in Capillary Flows James Sprittles Yulii Shikhmurzaev

2 What Is A Capillary Flow?! One in which surface tension is of importance –An effect caused by asymmetry of intermolecular forces. –Acts as a stretched elastic membrane at a surface. –Gradients in surface tension drive bulk motion (Marangoni effects). –Present at both liquid-gas and liquid-solid boundaries.

3 Introduction With: – A Big Computer – A Good Textbook – An Endless Supply of (Good) Coffee –A Lack of Social Life Can we describe all capillary flows?

4 1. A Classical Approach

5 The Classical Recipe In The Bulk: –(Incompressible) Navier–Stokes At Fluid Boundaries: –Balance of Stress With Capillary Forces. –Particles On a Free Surface, f(x,y,z,t)=0, Move With It (Kinematic Condition) At Solid Boundaries: –No Slip

6 Ink Jet Printing: Breakup of Liquid Threads A drop of ink is pushed from the nozzle.

7 Breakup of Liquid Threads Predictions of Classical Model: –Infinite Axial Velocity at Breakup. –Infinite Pressure at Breakup. –Rate of Fresh Free Surface Area Creation Becomes Infinite Main Problem: –Solution Required After Breakup.

8 Ink Jet Printing: Spreading of Liquids Drop In Equilibrium No Solution! Drop Out of Equilibrium Ink drops land and then spread on solid.

9 Coalescence Of Liquid Volumes Ink drops coalesce with adjacent ones on the paper. Infinite Stresses!

10 Ink Jet Printing: Impact On Chemically Patterned Surfaces Pattern a surface to correct deposition

11 Flow Over Chemically Patterned Surfaces Solid 1Solid 2 Predictions of The Classical Recipe

12 Molecular Dynamics Simulations of Flow Over Chemically Patterned Surfaces Courtesy of Professor N.V. Priezjev More wettable Compressed More wettable Compressed Less wettable Rarefied Less wettable Rarefied No – Slip = No Effect!

13 Also - Flow Generated By Rotating Cylinders Formation of a Cusp/Corner The Free Surface Is a Streamline.

14 Summary No Solution –Flow of Liquids Over Solids Singular Solution –Coalescence of Drops –Cusps –Breakup Of Liquids Wrong Solution –Flow Over Chemically Patterned Surfaces A Big Computer Can’t Handle These.

15 2. A Standard Approach

16 Flow Of Liquids Over Solids Two Issues: –Allow For A Solution –Describe The Angle Between The Free Surface and the Solid (The Contact Angle). U Standard Solution: –Allow Slip Between Solid and Liquid –Let

17 Q)Does The Standard Model Work? Impact of a Microdrop Radius = 25  m, Impact Speed = 12.2 m/s Re=345, We=51, β = 100,. Experiments of Dong 06. My Simulation

18 Q)Does The Standard Model Work? MySimulationMySimulation Experiment: Renardy et al

19 A) Yes and No! Experimentally Prediction of Standard Model Standard Model’s Problems: Incorrect Kinematics Pressure Singularity at Contact Line Contact Angle Depends on Flow U, m/s U

20 3. A New (ish) Approach

21 Breakup Of Liquid Threads New free surface is created. New free surface particles are initially out of equilibrium.

22 Spreading of Liquids on Solids Solid Gas Liquid In Frame Moving With Drop Interfaces are shown with finite thickness for representation only.

23 Coalescence Of Liquid Volumes Particles on the surface become trapped in the bulk.

24 Coalescence Of Liquid Volumes

25 Near Cusp/Corner Gas Liquid Corner/Cusp Interfaces are shown with finite thickness for representation only.

26 Surface Tension Relaxation

27 Summary All are associated with transition from one surface tension to another Relaxation of surface tension takes finite time/distance Mass, momentum and energy exchange between surface and bulk Gradients in surface tension (Marangoni effect)

28 Simplest Model of Interface Formation In the bulk: On liquid-solid interfaces:On free surfaces: At contact lines: θdθd e2e2 e1e1 n n f (r, t )=0 Generalisation of standard/classical model

29 Predictions/Propaganda Generalises standard/classical recipe. Removes singularities inherent in both classical and standard approaches. Predicts contact angle depends on flow field. Ensures one can (numerically) apply a unified approach to all these problems (=easier!). Agrees with experiment.

30 Conclusion/Sales Pitch With: – A Big Computer – An Endless Supply of (Good) Coffee –A Lack of Social Life –The RIGHT Textbook.. We can describe capillary flows!

31

32 Chemically Patterned Surface Surfaces With Wettability Gradients

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