Dynamics of the Ericksen–Leslie equations with general Leslie stress I: the incompressible isotropic case

Matthias Georg Hieber; Jan Prüss

doi:10.1007/s00208-016-1453-7

Dynamics of the Ericksen–Leslie equations with general Leslie stress I: the incompressible isotropic case

Matthias Georg Hieber^*, Jan Prüss

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

15 Citations (Scopus)

Abstract

The Ericksen–Leslie model for nematic liquid crystals in a bounded domain with general Leslie and isotropic Ericksen stress tensor is studied in the case of a non-isothermal and incompressible fluid. This system is shown to be locally strongly well-posed in the (Formula presented.)-setting, and a dynamical theory is developed. The equilibria are identified and shown to be normally stable. In particular, a local solution extends to a unique, global strong solution provided the initial data are close to an equilibrium or the solution is eventually bounded in the topology of the natural state manifold. In this case, the solution converges exponentially to an equilibrium, in the topology of the state manifold. The above results are proven without any structural assumptions on the Leslie coefficients and in particular without assuming Parodi’s relation.

Original language	English
Pages (from-to)	1-20
Number of pages	20
Journal	Mathematische Annalen
DOIs	https://doi.org/10.1007/s00208-016-1453-7
Publication status	Accepted/In press - 2016 Aug 2
Externally published	Yes

ASJC Scopus subject areas

Mathematics(all)

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title = "Dynamics of the Ericksen–Leslie equations with general Leslie stress I: the incompressible isotropic case",

abstract = "The Ericksen–Leslie model for nematic liquid crystals in a bounded domain with general Leslie and isotropic Ericksen stress tensor is studied in the case of a non-isothermal and incompressible fluid. This system is shown to be locally strongly well-posed in the (Formula presented.)-setting, and a dynamical theory is developed. The equilibria are identified and shown to be normally stable. In particular, a local solution extends to a unique, global strong solution provided the initial data are close to an equilibrium or the solution is eventually bounded in the topology of the natural state manifold. In this case, the solution converges exponentially to an equilibrium, in the topology of the state manifold. The above results are proven without any structural assumptions on the Leslie coefficients and in particular without assuming Parodi{\textquoteright}s relation.",

author = "Hieber, {Matthias Georg} and Jan Pr{\"u}ss",

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T1 - Dynamics of the Ericksen–Leslie equations with general Leslie stress I

T2 - the incompressible isotropic case

AU - Hieber, Matthias Georg

AU - Prüss, Jan

PY - 2016/8/2

Y1 - 2016/8/2

N2 - The Ericksen–Leslie model for nematic liquid crystals in a bounded domain with general Leslie and isotropic Ericksen stress tensor is studied in the case of a non-isothermal and incompressible fluid. This system is shown to be locally strongly well-posed in the (Formula presented.)-setting, and a dynamical theory is developed. The equilibria are identified and shown to be normally stable. In particular, a local solution extends to a unique, global strong solution provided the initial data are close to an equilibrium or the solution is eventually bounded in the topology of the natural state manifold. In this case, the solution converges exponentially to an equilibrium, in the topology of the state manifold. The above results are proven without any structural assumptions on the Leslie coefficients and in particular without assuming Parodi’s relation.

AB - The Ericksen–Leslie model for nematic liquid crystals in a bounded domain with general Leslie and isotropic Ericksen stress tensor is studied in the case of a non-isothermal and incompressible fluid. This system is shown to be locally strongly well-posed in the (Formula presented.)-setting, and a dynamical theory is developed. The equilibria are identified and shown to be normally stable. In particular, a local solution extends to a unique, global strong solution provided the initial data are close to an equilibrium or the solution is eventually bounded in the topology of the natural state manifold. In this case, the solution converges exponentially to an equilibrium, in the topology of the state manifold. The above results are proven without any structural assumptions on the Leslie coefficients and in particular without assuming Parodi’s relation.

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Dynamics of the Ericksen–Leslie equations with general Leslie stress I: the incompressible isotropic case

Abstract

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