Saffman-Taylor fingers with kinetic undercooling

The selection of Saffman–Taylor fingers by surface tension has been extensively investigated. In this paper, we are concerned with the existence and selection of steadily translating symmetric finger solutions in a Hele–Shaw cell by small but non-zero kinetic undercooling (ε2). We rigorously conclude that for relative finger width λ near one half, symmetric finger solutions exist in the asymptotic limit of undercooling ε2 → 0 if the Stokes multiplier for a relatively simple non-linear differential equation is zero. This Stokes multiplier S depends on the parameter $\alpha \equiv \frac{2 \lambda -1}{(1-\lambda)}\epsilon^{-\frac{4}{3}}$ and earlier calculations have shown this to be zero for a discrete set of values of α. While this result is similar to that obtained previously for Saffman–Taylor fingers by surface tension, the analysis for the problem with kinetic undercooling exhibits a number of subtleties as pointed out by Chapman and King (2003, The selection of Saffman–Taylor fingers by kinetic undercooling, Journal of Engineering Mathematics, 46, 1–32). The main subtlety is the behaviour of the Stokes lines at the finger tip, where the analysis is complicated by non-analyticity of coefficients in the governing equation.

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Macroscopic models for melting derived from averaging microscopic Stefan problems I: Simple geometries with kinetic undercooling or surface tension

European Journal of Applied Mathematics ◽

10.1017/s0956792599004027 ◽

2000 ◽

Vol 11 (2) ◽

pp. 153-169 ◽

Cited By ~ 14

Author(s):

A. A. LACEY ◽

L. A. HERRAIZ

Keyword(s):

Free Boundary ◽

Multiple Scales ◽

Two Dimensions ◽

Macroscopic Model ◽

Mushy Region ◽

Free Boundaries ◽

Two Phase ◽

Macroscopic Models ◽

Stefan Problems ◽

Kinetic Undercooling

A mushy region is assumed to consist of a fine mixture of two distinct phases separated by free boundaries. For simplicity, the fine structure is here taken to be periodic, first in one dimension, and then a lattice of squares in two dimensions. A method of multiple scales is employed, with a classical free-boundary problem being used to model the evolution of the two-phase microstructure. Then a macroscopic model for the mush is obtained by an averaging procedure. The free-boundary temperature is taken to vary according to Gibbs–Thomson and/or kinetic-undercooling effects.

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Mathematical modelling of Tyndall star initiation

European Journal of Applied Mathematics ◽

10.1017/s095679251500042x ◽

2015 ◽

Vol 26 (5) ◽

pp. 615-645 ◽

Cited By ~ 1

Author(s):

A. A. LACEY ◽

M. G. HENNESSY ◽

P. HARVEY ◽

R. F. KATZ

Keyword(s):

Mathematical Model ◽

Free Boundary ◽

Free Boundary Problems ◽

Liquid Interfaces ◽

Boundary Problems ◽

Volumetric Heating ◽

Crystalline Anisotropy ◽

Kinetic Undercooling ◽

Interesting Class ◽

Solid Liquid

The superheating that usually occurs when a solid is melted by volumetric heating can produce irregular solid–liquid interfaces. Such interfaces can be visualised in ice, where they are sometimes known as Tyndall stars. This paper describes some of the experimental observations of Tyndall stars and a mathematical model for the early stages of their evolution. The modelling is complicated by the strong crystalline anisotropy, which results in an anisotropic kinetic undercooling at the interface; it leads to an interesting class of free boundary problems that treat the melt region as infinitesimally thin.

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The LSW model for Ostwald ripening with kinetic undercooling

Proceedings of the Royal Society of Edinburgh Section A Mathematics ◽

10.1017/s0308210500000718 ◽

2000 ◽

Vol 130 (6) ◽

pp. 1337-1361 ◽

Cited By ~ 12

Author(s):

Barbara Niethammer

Keyword(s):

Surface Tension ◽

Liquid Phase ◽

Field Model ◽

Ostwald Ripening ◽

Solid Phase ◽

Mean Field ◽

Undercooled Liquid ◽

Small Particles ◽

Mean Field Model ◽

Kinetic Undercooling

We study a Stefan problem for coarsening of many small particles of solid phase in undercooled liquid phase which includes surface tension and kinetic undercooling effects. A mean-field model is derived by homogenization of the free boundary problem. It extends the classical theory of Lifshitz et al. by taking into account effects due to kinetic undercooling.

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Macroscopic models for melting derived from averaging microscopic Stefan problems II: Effect of varying geometry and composition

European Journal of Applied Mathematics ◽

10.1017/s0956792501004818 ◽

2002 ◽

Vol 13 (3) ◽

pp. 261-282 ◽

Cited By ~ 8

Author(s):

A. A. LACEY ◽

L. A. HERRAIZ

Keyword(s):

Alloy Composition ◽

Multiple Scales ◽

Method Of Multiple Scales ◽

Macroscopic Model ◽

Mushy Region ◽

Free Boundaries ◽

Final Model ◽

Macroscopic Models ◽

Stefan Problems ◽

Kinetic Undercooling

A mushy region is assumed to consist of a fine mixture of two distinct phases separated by free boundaries. A method of multiple scales, with restrictions on the form of the microscopic free boundaries, is used to derive a macroscopic model for the mushy region. The final model depends both on the microscopic structure and on how the free-boundary temperature varies with curvature (Gibbs–Thomson effect), kinetic undercooling, or, for an alloy, composition.

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Corner and finger formation in Hele-Shaw flow with kinetic undercooling regularisation

European Journal of Applied Mathematics ◽

10.1017/s0956792514000230 ◽

2014 ◽

Vol 25 (6) ◽

pp. 707-727 ◽

Cited By ~ 7

Author(s):

MICHAEL C. DALLASTON ◽

SCOTT W. McCUE

Keyword(s):

Viscous Fluid ◽

Finite Time ◽

Analytic Solutions ◽

Flow Rule ◽

Geometric Flow ◽

Numerical Solution Method ◽

Kinetic Undercooling ◽

Finger Width ◽

Loss Of Regularity ◽

Discrete Family

We examine the effect of a kinetic undercooling condition on the evolution of a free boundary in Hele-Shaw flow, in both bubble and channel geometries. We present analytical and numerical evidence that the bubble boundary is unstable and may develop one or more corners in finite time, for both expansion and contraction cases. This loss of regularity is interesting because it occurs regardless of whether the less viscous fluid is displacing the more viscous fluid, or vice versa. We show that small contracting bubbles are described to leading order by a well-studied geometric flow rule. Exact solutions to this asymptotic problem continue past the corner formation until the bubble contracts to a point as a slit in the limit. Lastly, we consider the evolving boundary with kinetic undercooling in a Saffman-Taylor channel geometry. The boundary may either form corners in finite time, or evolve to a single long finger travelling at constant speed, depending on the strength of kinetic undercooling. We demonstrate these two different behaviours numerically. For the travelling finger, we present results of a numerical solution method similar to that used to demonstrate the selection of discrete fingers by surface tension. With kinetic undercooling, a continuum of corner-free travelling fingers exists for any finger width above a critical value, which goes to zero as the kinetic undercooling vanishes. We have not been able to compute the discrete family of analytic solutions, predicted by previous asymptotic analysis, because the numerical scheme cannot distinguish between solutions characterised by analytic fingers and those which are corner-free but non-analytic.

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