Role of Interaction between Magnetic Rossby Waves and Tachocline Differential Rotation in Producing Solar Seasons

We present a nonlinear magnetohydrodynamic shallow-water model for the solar tachocline (MHD-SWT) that generates quasi-periodic tachocline nonlinear oscillations (TNOs) that can be identified with the recently discovered solar "seasons." We discuss the properties of the hydrodynamic and ma...

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Veröffentlicht in:	The Astrophysical journal 2018-02, Vol.853 (2), p.144
Hauptverfasser:	Dikpati, Mausumi, McIntosh, Scott W., Bothun, Gregory, Cally, Paul S., Ghosh, Siddhartha S., Gilman, Peter A., Umurhan, Orkan M.
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Sprache:	eng
Schlagworte:	Astrophysics Computational fluid dynamics Computer simulation Differential rotation Energy Energy conversion Energy flow Energy transfer Exchanging Flow mapping Fluid flow Hemispheres instabilities Magnetic fields Magnetic properties Magnetohydrodynamics magnetohydrodynamics (MHD) Oscillations Physical simulation Planetary waves Rossby waves Seasons Sun: activity Sun: magnetic fields Sun: rotation
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container_title	The Astrophysical journal
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description	We present a nonlinear magnetohydrodynamic shallow-water model for the solar tachocline (MHD-SWT) that generates quasi-periodic tachocline nonlinear oscillations (TNOs) that can be identified with the recently discovered solar "seasons." We discuss the properties of the hydrodynamic and magnetohydrodynamic Rossby waves that interact with the differential rotation and toroidal fields to sustain these oscillations, which occur due to back-and-forth energy exchanges among potential, kinetic, and magnetic energies. We perform model simulations for a few years, for selected example cases, in both hydrodynamic and magnetohydrodynamic regimes and show that the TNOs are robust features of the MHD-SWT model, occurring with periods of 2-20 months. We find that in certain cases multiple unstable shallow-water modes govern the dynamics, and TNO periods vary with time. In hydrodynamically governed TNOs, the energy exchange mechanism is simple, occurring between the Rossby waves and differential rotation. But in MHD cases, energy exchange becomes much more complex, involving energy flow among six energy reservoirs by means of eight different energy conversion processes. For toroidal magnetic bands of 5 and 35 kG peak amplitudes, both placed at 45° latitude and oppositely directed in north and south hemispheres, we show that the energy transfers responsible for TNO, as well as westward phase propagation, are evident in synoptic maps of the flow, magnetic field, and tachocline top-surface deformations. Nonlinear mode-mode interaction is particularly dramatic in the strong-field case. We also find that the TNO period increases with a decrease in rotation rate, implying that the younger Sun had more frequent seasons.
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We discuss the properties of the hydrodynamic and magnetohydrodynamic Rossby waves that interact with the differential rotation and toroidal fields to sustain these oscillations, which occur due to back-and-forth energy exchanges among potential, kinetic, and magnetic energies. We perform model simulations for a few years, for selected example cases, in both hydrodynamic and magnetohydrodynamic regimes and show that the TNOs are robust features of the MHD-SWT model, occurring with periods of 2-20 months. We find that in certain cases multiple unstable shallow-water modes govern the dynamics, and TNO periods vary with time. In hydrodynamically governed TNOs, the energy exchange mechanism is simple, occurring between the Rossby waves and differential rotation. But in MHD cases, energy exchange becomes much more complex, involving energy flow among six energy reservoirs by means of eight different energy conversion processes. For toroidal magnetic bands of 5 and 35 kG peak amplitudes, both placed at 45° latitude and oppositely directed in north and south hemispheres, we show that the energy transfers responsible for TNO, as well as westward phase propagation, are evident in synoptic maps of the flow, magnetic field, and tachocline top-surface deformations. Nonlinear mode-mode interaction is particularly dramatic in the strong-field case. We also find that the TNO period increases with a decrease in rotation rate, implying that the younger Sun had more frequent seasons.</description><identifier>ISSN: 0004-637X</identifier><identifier>EISSN: 1538-4357</identifier><identifier>DOI: 10.3847/1538-4357/aaa70d</identifier><language>eng</language><publisher>Philadelphia: The American Astronomical Society</publisher><subject>Astrophysics ; Computational fluid dynamics ; Computer simulation ; Differential rotation ; Energy ; Energy conversion ; Energy flow ; Energy transfer ; Exchanging ; Flow mapping ; Fluid flow ; Hemispheres ; instabilities ; Magnetic fields ; Magnetic properties ; Magnetohydrodynamics ; magnetohydrodynamics (MHD) ; Oscillations ; Physical simulation ; Planetary waves ; Rossby waves ; Seasons ; Sun: activity ; Sun: magnetic fields ; Sun: rotation</subject><ispartof>The Astrophysical journal, 2018-02, Vol.853 (2), p.144</ispartof><rights>2018. The American Astronomical Society. 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J</addtitle><description>We present a nonlinear magnetohydrodynamic shallow-water model for the solar tachocline (MHD-SWT) that generates quasi-periodic tachocline nonlinear oscillations (TNOs) that can be identified with the recently discovered solar "seasons." We discuss the properties of the hydrodynamic and magnetohydrodynamic Rossby waves that interact with the differential rotation and toroidal fields to sustain these oscillations, which occur due to back-and-forth energy exchanges among potential, kinetic, and magnetic energies. We perform model simulations for a few years, for selected example cases, in both hydrodynamic and magnetohydrodynamic regimes and show that the TNOs are robust features of the MHD-SWT model, occurring with periods of 2-20 months. We find that in certain cases multiple unstable shallow-water modes govern the dynamics, and TNO periods vary with time. In hydrodynamically governed TNOs, the energy exchange mechanism is simple, occurring between the Rossby waves and differential rotation. But in MHD cases, energy exchange becomes much more complex, involving energy flow among six energy reservoirs by means of eight different energy conversion processes. For toroidal magnetic bands of 5 and 35 kG peak amplitudes, both placed at 45° latitude and oppositely directed in north and south hemispheres, we show that the energy transfers responsible for TNO, as well as westward phase propagation, are evident in synoptic maps of the flow, magnetic field, and tachocline top-surface deformations. Nonlinear mode-mode interaction is particularly dramatic in the strong-field case. We also find that the TNO period increases with a decrease in rotation rate, implying that the younger Sun had more frequent seasons.</description><subject>Astrophysics</subject><subject>Computational fluid dynamics</subject><subject>Computer simulation</subject><subject>Differential rotation</subject><subject>Energy</subject><subject>Energy conversion</subject><subject>Energy flow</subject><subject>Energy transfer</subject><subject>Exchanging</subject><subject>Flow mapping</subject><subject>Fluid flow</subject><subject>Hemispheres</subject><subject>instabilities</subject><subject>Magnetic fields</subject><subject>Magnetic properties</subject><subject>Magnetohydrodynamics</subject><subject>magnetohydrodynamics (MHD)</subject><subject>Oscillations</subject><subject>Physical simulation</subject><subject>Planetary waves</subject><subject>Rossby waves</subject><subject>Seasons</subject><subject>Sun: activity</subject><subject>Sun: magnetic fields</subject><subject>Sun: rotation</subject><issn>0004-637X</issn><issn>1538-4357</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2018</creationdate><recordtype>article</recordtype><recordid>eNp1kM1LAzEQxYMoWKt3jwGvrk03X7tHqV-FitJW9Bay2aSmrElNUqX_vbuu6Mm5DDO894b5AXA6Rhe4IHw0prjICKZ8JKXkqN4Dg9_VPhgghEjGMH85BEcxrrsxL8sBeJ_7RkNv4NQlHaRK1jtY6fSptYP3cuV0sgrOfYzVDj7LDx2hdDVcSvXqVWOdhlfWGB20S1Y2rTDJ7wjr4GPw9VZZt4IL38gAF1pG7-IxODCyifrkpw_B0831cnKXzR5up5PLWaYwRSljvMSmJAyzkrOyqgtDkSI1IpQyVavKIIUVohQTUiJSUFoagpAmvBrzPEc5HoKzPncT_PtWxyTWfhtce1LkmFHOWVutCvUqFdofgzZiE-ybDDsxRqIDKzqKoqMoerCt5by3WL_5y_xX_gU0HnnA</recordid><startdate>20180201</startdate><enddate>20180201</enddate><creator>Dikpati, Mausumi</creator><creator>McIntosh, Scott W.</creator><creator>Bothun, Gregory</creator><creator>Cally, Paul S.</creator><creator>Ghosh, Siddhartha S.</creator><creator>Gilman, Peter A.</creator><creator>Umurhan, Orkan M.</creator><general>The American Astronomical Society</general><general>IOP Publishing</general><scope>AAYXX</scope><scope>CITATION</scope><scope>7TG</scope><scope>8FD</scope><scope>H8D</scope><scope>KL.</scope><scope>L7M</scope><orcidid>https://orcid.org/0000-0002-7369-1776</orcidid><orcidid>https://orcid.org/0000-0001-5794-8810</orcidid><orcidid>https://orcid.org/0000-0002-9515-6360</orcidid><orcidid>https://orcid.org/0000-0002-2227-0488</orcidid><orcidid>https://orcid.org/0000-0002-1639-6252</orcidid></search><sort><creationdate>20180201</creationdate><title>Role of Interaction between Magnetic Rossby Waves and Tachocline Differential Rotation in Producing Solar Seasons</title><author>Dikpati, Mausumi ; 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subjects	Astrophysics Computational fluid dynamics Computer simulation Differential rotation Energy Energy conversion Energy flow Energy transfer Exchanging Flow mapping Fluid flow Hemispheres instabilities Magnetic fields Magnetic properties Magnetohydrodynamics magnetohydrodynamics (MHD) Oscillations Physical simulation Planetary waves Rossby waves Seasons Sun: activity Sun: magnetic fields Sun: rotation
title	Role of Interaction between Magnetic Rossby Waves and Tachocline Differential Rotation in Producing Solar Seasons
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