Non-linear evolution of the tidal elliptical instability in gaseous planets and stars

Tidally distorted rotating stars and gaseous planets are subject to a well-known linear fluid instability - the elliptical instability. It has been proposed that this instability might drive enough energy dissipation to solve the long-standing problem of the origin of tidal dissipation in stars and...

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Veröffentlicht in:	Monthly notices of the Royal Astronomical Society 2013-11, Vol.435 (4), p.3614-3626
Hauptverfasser:	Barker, Adrian J., Lithwick, Yoram
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Sprache:	eng
Schlagworte:	Astronomy Boundary conditions Gases Magnetic fields Planets Stars & galaxies
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creator	Barker, Adrian J. Lithwick, Yoram
description	Tidally distorted rotating stars and gaseous planets are subject to a well-known linear fluid instability - the elliptical instability. It has been proposed that this instability might drive enough energy dissipation to solve the long-standing problem of the origin of tidal dissipation in stars and planets. But the non-linear outcome of the elliptical instability has yet to be investigated in the parameter regime of interest, and the resulting turbulent energy dissipation has not yet been quantified. We do so by performing three-dimensional hydrodynamical simulations of a small patch of a tidally deformed fluid planet or star subject to the elliptical instability. We show that when the tidal deformation is weak, the non-linear outcome of the instability leads to the formation of long-lived columnar vortices aligned with the axis of rotation. These vortices shut off the elliptical instability, and the net result is insufficient energy dissipation to account for tidal dissipation. However, further work is required to account for effects neglected here, including magnetic fields, turbulent convection and realistic boundary conditions.
doi_str_mv	10.1093/mnras/stt1561
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It has been proposed that this instability might drive enough energy dissipation to solve the long-standing problem of the origin of tidal dissipation in stars and planets. But the non-linear outcome of the elliptical instability has yet to be investigated in the parameter regime of interest, and the resulting turbulent energy dissipation has not yet been quantified. We do so by performing three-dimensional hydrodynamical simulations of a small patch of a tidally deformed fluid planet or star subject to the elliptical instability. We show that when the tidal deformation is weak, the non-linear outcome of the instability leads to the formation of long-lived columnar vortices aligned with the axis of rotation. These vortices shut off the elliptical instability, and the net result is insufficient energy dissipation to account for tidal dissipation. 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Not. R. Astron. Soc</addtitle><description>Tidally distorted rotating stars and gaseous planets are subject to a well-known linear fluid instability - the elliptical instability. It has been proposed that this instability might drive enough energy dissipation to solve the long-standing problem of the origin of tidal dissipation in stars and planets. But the non-linear outcome of the elliptical instability has yet to be investigated in the parameter regime of interest, and the resulting turbulent energy dissipation has not yet been quantified. We do so by performing three-dimensional hydrodynamical simulations of a small patch of a tidally deformed fluid planet or star subject to the elliptical instability. We show that when the tidal deformation is weak, the non-linear outcome of the instability leads to the formation of long-lived columnar vortices aligned with the axis of rotation. These vortices shut off the elliptical instability, and the net result is insufficient energy dissipation to account for tidal dissipation. 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Not. R. Astron. Soc</stitle><date>2013-11-11</date><risdate>2013</risdate><volume>435</volume><issue>4</issue><spage>3614</spage><epage>3626</epage><pages>3614-3626</pages><issn>0035-8711</issn><eissn>1365-2966</eissn><abstract>Tidally distorted rotating stars and gaseous planets are subject to a well-known linear fluid instability - the elliptical instability. It has been proposed that this instability might drive enough energy dissipation to solve the long-standing problem of the origin of tidal dissipation in stars and planets. But the non-linear outcome of the elliptical instability has yet to be investigated in the parameter regime of interest, and the resulting turbulent energy dissipation has not yet been quantified. We do so by performing three-dimensional hydrodynamical simulations of a small patch of a tidally deformed fluid planet or star subject to the elliptical instability. We show that when the tidal deformation is weak, the non-linear outcome of the instability leads to the formation of long-lived columnar vortices aligned with the axis of rotation. These vortices shut off the elliptical instability, and the net result is insufficient energy dissipation to account for tidal dissipation. However, further work is required to account for effects neglected here, including magnetic fields, turbulent convection and realistic boundary conditions.</abstract><cop>London</cop><pub>Oxford University Press</pub><doi>10.1093/mnras/stt1561</doi><tpages>13</tpages><oa>free_for_read</oa></addata></record>
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subjects	Astronomy Boundary conditions Gases Magnetic fields Planets Stars & galaxies
title	Non-linear evolution of the tidal elliptical instability in gaseous planets and stars
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