Geodesic
Maximal regularity of the spatially periodic Stokes operator and application to nematic liquid crystal flows
Czechoslovak Mathematical Journal, Tome 66 (2016) no. 1, pp. 41-55 Cet article a éte moissonné depuis la source Czech Digital Mathematics Library

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We consider the dynamics of spatially periodic nematic liquid crystal flows in the whole space and prove existence and uniqueness of local-in-time strong solutions using maximal $L^p$-regularity of the periodic Laplace and Stokes operators and a local-in-time existence theorem for quasilinear parabolic equations à la Clément-Li (1993). Maximal regularity of the Laplace and the Stokes operator is obtained using an extrapolation theorem on the locally compact abelian group $G:=\mathbb R^{n-1}\times \mathbb R / L \mathbb Z$ to obtain an $\mathcal {R}$-bound for the resolvent estimate. Then, Weis' theorem connecting $\mathcal {R}$-boundedness of the resolvent with maximal $L^p$ regularity of a sectorial operator applies.
We consider the dynamics of spatially periodic nematic liquid crystal flows in the whole space and prove existence and uniqueness of local-in-time strong solutions using maximal $L^p$-regularity of the periodic Laplace and Stokes operators and a local-in-time existence theorem for quasilinear parabolic equations à la Clément-Li (1993). Maximal regularity of the Laplace and the Stokes operator is obtained using an extrapolation theorem on the locally compact abelian group $G:=\mathbb R^{n-1}\times \mathbb R / L \mathbb Z$ to obtain an $\mathcal {R}$-bound for the resolvent estimate. Then, Weis' theorem connecting $\mathcal {R}$-boundedness of the resolvent with maximal $L^p$ regularity of a sectorial operator applies.
DOI : 10.1007/s10587-016-0237-2
Classification : 35B10, 35K59, 35Q35, 76A15, 76D03
Keywords: Stokes operator; spatially periodic problem; maximal $L^p$ regularity; nematic liquid crystal flow; quasilinear parabolic equations 
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Sauer, Jonas. Maximal regularity of the spatially periodic Stokes operator and application to nematic liquid crystal flows. Czechoslovak Mathematical Journal, Tome 66 (2016) no. 1, pp. 41-55. doi: 10.1007/s10587-016-0237-2

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