Electroconvection of thin liquid crystals: Model reduction and numerical simulations

Bonito, Andrea; Wei, Peng

doi:10.1016/j.jcp.2019.109140

Cited by 5 publications

(2 citation statements)

References 34 publications

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“…Fractional partial differential equations (FPDEs) have gained in popularity during the last two decades and are now applied in a wide range of fields [71] such as anomalous diffusion [27,40,49,54,75], electromagnetism and geophysical electromagnetism [24,82], phase fluids [9,11,53], porous media [11,39,20,35], quasi-geostrophic flows [22] and spatial statistics [21,70].…”

Section: Introductionmentioning

confidence: 99%

An a posteriori error estimator for the spectral fractional power of the Laplacian

Bulle,

Barrera,

Bordas

et al. 2022

Preprint

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We develop a novel a posteriori error estimator for the L 2 error committed by the finite element discretization of the solution of the fractional Laplacian. Our a posteriori error estimator takes advantage of the semi-discretization scheme using a rational approximation which allows to reformulate the fractional problem into a family of non-fractional parametric problems. The estimator involves applying the implicit Bank-Weiser error estimation strategy to each parametric non-fractional problem and reconstructing the fractional error through the same rational approximation used to compute the solution to the original fractional problem. We provide several numerical examples in both two and three-dimensions demonstrating the effectivity of our estimator for varying fractional powers and its ability to drive an adaptive mesh refinement strategy.

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Section: Introductionmentioning

confidence: 99%

An a posteriori error estimator for the spectral fractional power of the Laplacian

Bulle,

Barrera,

Bordas

et al. 2022

Preprint

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“…The case κ = 0 will be referred to as the inviscid case. A detailed derivation of the SQG system can be found in [59], based on the works [47,14,31,37,32] and [8,55]. The above nonlinear system of equations features many aspect of large-scale atmospheric motions.…”

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confidence: 99%

Numerical Simulations of Surface-Quasi Geostrophic Flows on Periodic Domains

Bonito¹,

Nazarov²

2020

Preprint

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We propose a novel algorithm for the approximation of surface-quasi geostrophic (SQG) flows modeled by a nonlinear partial differential equation coupling transport and fractional diffusion phenomena. The time discretization consists of an explicit strong-stability-preserving threestage Runge-Kutta method while a flux-corrected-transport (FCT) method coupled with Dunford-Taylor representations of fractional operators is advocated for the space discretization. Standard continuous piecewise linear finite elements are employed and the algorithm does not have restrictions on the mesh structure nor on the computational domain. In the inviscid case, we show that the resulting scheme satisfies a discrete maximum principle property under a standard CFL condition and observe, in practice, its second-order accuracy in space. The algorithm successfully approximates several benchmarks with sharp transitions and fine structures typical of SQG flows. In addition, theoretical Kolmogorov energy decay rates are observed on a freely decaying atmospheric turbulence simulation.

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Fractional-order dependent Radial basis functions meshless methods for the integral fractional Laplacian

Hao,

Cai,

Zhang

2025

Computers & Mathematics with Applications

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Electroconvection of thin liquid crystals: Model reduction and numerical simulations

Cited by 5 publications

References 34 publications

An a posteriori error estimator for the spectral fractional power of the Laplacian

An a posteriori error estimator for the spectral fractional power of the Laplacian

Numerical Simulations of Surface-Quasi Geostrophic Flows on Periodic Domains

Fractional-order dependent Radial basis functions meshless methods for the integral fractional Laplacian

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