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A Research Note on a Solution of Stefan Problem with Fractional Time and Space Derivatives


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Abstract


Stefan problem based on nonlocal heat conduction equation with fractional-time derivatives has been solved. The approach suggests a generalized time-dependent Stefan boundary condition defined by expression ϑ(α, β, τ) = σ(α, β)τ^(α/β). The solution developed shows that the phase change boundary co-ordinate ϑ depends on time τ and the parameters α (0<α≤1) and β (1<β≤2) which are the fractional orders with respect to the time and the space co-ordinate , respectively. A practical example with ice-water system was used to exemplify the solution with both α and β near to α = 1 and β = 1 (the classical problem).
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Keywords


Fractional Derivative; Nonlocal Heat Conduction Equation; Stefan Problem

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References


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