2020
DOI: 10.1017/s095679252000011x
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Extended Stefan problem for the solidification of binary alloys in a sphere

Abstract: We study the extended Stefan problem which includes constitutional supercooling for the solidification of a binary alloy in a finite spherical domain. We perform an asymptotic analysis in the limits of large Lewis number and small Stefan number which allows us to identify a number of spatio-temporal regimes signifying distinct behaviours in the solidification process, resulting in an intricate boundary layer structure. Our results generalise those present in the literature by considering all time regimes for t… Show more

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Cited by 20 publications
(12 citation statements)
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“…Heat maps in Figure 9(a)-(b) compare numerical estimates of κ from the phase plane with the perturbation result, Equation (33). The heat map of δκ = κ − κ p in Figure 9(c) shows that the O(c −8 ) perturbation solutions leads to extremely accurate solutions for κ for c < −2 for all u f .…”
Section: Fast Retreating Travelling Wavesmentioning
confidence: 88%
See 1 more Smart Citation
“…Heat maps in Figure 9(a)-(b) compare numerical estimates of κ from the phase plane with the perturbation result, Equation (33). The heat map of δκ = κ − κ p in Figure 9(c) shows that the O(c −8 ) perturbation solutions leads to extremely accurate solutions for κ for c < −2 for all u f .…”
Section: Fast Retreating Travelling Wavesmentioning
confidence: 88%
“…given by a classical one-phase Stefan condition ds(t)/dt = −κ∂u(s(t), t)/∂x [25][26][27][28][29][30][31][32][33], has been called the Fisher-…”
Section: Various Mathematical Extensions Have Been Proposed To Overco...mentioning
confidence: 99%
“…Moving-boundary problems of this type are traditionally used to model physical and industrial processes [26][27][28][29][30]. Indeed, the boundary condition (1.3) is analogous to the classical Stefan condition [31] for a material undergoing phase change, where κ is the inverse Stefan number.…”
Section: Introductionmentioning
confidence: 99%
“…Moving boundary problems are frequently used to model phenomena in physics, in particular melting/freezing processes where the moving boundary represents a solid/melt interface [1][2][3] or interfacial flow problems where the moving boundary is the interface between two fluids [4]. In diffusion-driven process, a moving boundary can be driven by swelling of one phase, for example a polymer or a porous material [5][6][7] One key motivation from a physics perspective is to use moving boundary problems to describe pattern formation at the interface, such as that which occurs when a crystal forms from a supercooled melt [8,9] or when viscous fingering develops in a Hele-Shaw cell [10,11].…”
Section: Introductionmentioning
confidence: 99%