Asymptotically compatible energy and dissipation law of the nonuniform L2-1σ scheme for time fractional Allen-Cahn model
Abstract
We build an asymptotically compatible energy of the variable-step L2-1σ scheme for the time-fractional Allen-Cahn model with the Caputo's fractional derivative of order α∈(0,1), under a weak step-ratio constraint τk/τk-1≥ r(α) for k2, where τk is the k-th time-step size and r(α)∈(0.3865,0.4037) for α∈(0,1). It provides a positive answer to the open problem in [J. Comput. Phys., 414:109473], and, to the best of our knowledge, it is the first second-order nonuniform time-stepping scheme to preserve both the maximum bound principle and the energy dissipation law of time-fractional Allen-Cahn model. The compatible discrete energy is constructed via a novel discrete gradient structure of the second-order L2-1σ formula by a local-nonlocal splitting technique. It splits the discrete fractional derivative into two parts: one is a local term analogue to the trapezoid rule of the first derivative and the other is a nonlocal summation analogue to the L1 formula of Caputo derivative. Numerical examples with an adaptive time-stepping strategy are provided to show the effectiveness of our scheme and the asymptotic properties of the associated modified energy.
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