On the dynamical nature of Saturn’s North Polar hexagon

An explanation of long-lived Saturn’s North Polar hexagonal circumpolar jetin terms of instability of the coupled system polar vortex - circumpolar jet isproposed in the framework of the rotating shallow water model, wherescarcely known vertical structure of the Saturn’s atmosphere is averaged out.T...

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Main Author: , LMD
Format: Report
Language:unknown
Published: Open Science Framework 2018
Subjects:
The Sun and the Solar System
Other Computer Sciences
Statistical, Nonlinear, and Soft Matter Physics
Astrophysics and Astronomy
Partial Differential Equations
Categorical Data Analysis
Other Earth Sciences
FOS Earth and related environmental sciences
Numerical Analysis and Computation
Numerical Analysis and Scientific Computing
Tectonics and Structure
Other Applied Mathematics
Plasma and Beam Physics
OS and Networks
Statistics and Probability
Statistical Methodology
Stratigraphy
Geophysics and Seismology
Physical Sciences and Mathematics
Applied Mathematics
FOS Mathematics
Information Security
Ordinary Differential Equations and Applied Dynamics
Stars, Interstellar Medium and the Galaxy
Other Astrophysics and Astronomy
Cosmology, Relativity, and Gravity
Paleobiology
Instrumentation
Environmental Sciences
Probability
Graphics and Human Computer Interfaces
Geology
Special Functions
Mathematics
Non-linear Dynamics
Cosmochemistry
Earth Sciences
Computer Sciences
Geomorphology
Physics
External Galaxies
Design of Experiments and Sample Surveys
Applied Statistics
Fluid Dynamics
Physical Processes
Institutional and Historical
Dynamic Systems
Statistical Theory
Artificial Intelligence and Robotics
Glaciology
Databases and Information Systems
Other Physics
South Pole
South pole
Online Access:https://dx.doi.org/10.17605/osf.io/rvdmx
https://osf.io/rvdmx/
id ftdatacite:10.17605/osf.io/rvdmx
record_format openpolar
spelling ftdatacite:10.17605/osf.io/rvdmx 2023-05-15T18:23:23+02:00 On the dynamical nature of Saturn’s North Polar hexagon , LMD 2018 https://dx.doi.org/10.17605/osf.io/rvdmx https://osf.io/rvdmx/ unknown Open Science Framework https://dx.doi.org/10.1016/j.icarus.2017.06.006 CC0 1.0 Universal CC0 The Sun and the Solar System Other Computer Sciences Statistical, Nonlinear, and Soft Matter Physics Astrophysics and Astronomy Partial Differential Equations Categorical Data Analysis Other Earth Sciences FOS Earth and related environmental sciences Numerical Analysis and Computation Numerical Analysis and Scientific Computing Tectonics and Structure Other Applied Mathematics Plasma and Beam Physics OS and Networks Statistics and Probability Statistical Methodology Stratigraphy Geophysics and Seismology Physical Sciences and Mathematics Applied Mathematics FOS Mathematics Information Security Ordinary Differential Equations and Applied Dynamics Stars, Interstellar Medium and the Galaxy Other Astrophysics and Astronomy Cosmology, Relativity, and Gravity Paleobiology Instrumentation Environmental Sciences Probability Graphics and Human Computer Interfaces Geology Special Functions Mathematics Non-linear Dynamics Cosmochemistry Earth Sciences Computer Sciences Geomorphology Physics External Galaxies Design of Experiments and Sample Surveys Applied Statistics Fluid Dynamics Physical Processes Institutional and Historical Dynamic Systems Statistical Theory Artificial Intelligence and Robotics Glaciology Databases and Information Systems Other Physics Preprint Text article-journal ScholarlyArticle 2018 ftdatacite https://doi.org/10.17605/osf.io/rvdmx 2021-11-05T12:55:41Z An explanation of long-lived Saturn’s North Polar hexagonal circumpolar jetin terms of instability of the coupled system polar vortex - circumpolar jet isproposed in the framework of the rotating shallow water model, wherescarcely known vertical structure of the Saturn’s atmosphere is averaged out.The absence of a hexagonal structure at Saturn’s South Pole is explainedsimilarly. By using the latest state-of-the-art observed winds in Saturn’spolar regions a detailed linear stability analysis of the circumpolar jet isperformed (i) excluding (“jet-only” configuration), and (2) including(“jet+vortex” configuration) the north polar vortex in the system. A domainof parameters: latitude of the circumpolar jet and curvature of its azimuthalvelocity profile, where the most unstable mode of the system has azimuthalwavenumber 6, is identified. Fully nonlinear simulations are then performed,initialized either with the most unstable mode of small amplitude, or withthe random combination of unstable modes. It is shown that developingbarotropic instability of the “jet+vortex” system produces a long-livingstructure akin to the observed hexagon, which is not the case of the“jet-only” system, which was studied in this context in a number of papersin literature. The north polar vortex, thus, plays a decisive dynamical role.The influence of moist convection, which was recently suggested to be at theorigin of Saturn’s north polar vortex system in the literature, is investigatedin the framework of the model and does not alter the conclusions. Report South pole DataCite Metadata Store (German National Library of Science and Technology) South Pole
institution Open Polar
collection DataCite Metadata Store (German National Library of Science and Technology)
op_collection_id ftdatacite
language unknown
topic The Sun and the Solar System
Other Computer Sciences
Statistical, Nonlinear, and Soft Matter Physics
Astrophysics and Astronomy
Partial Differential Equations
Categorical Data Analysis
Other Earth Sciences
FOS Earth and related environmental sciences
Numerical Analysis and Computation
Numerical Analysis and Scientific Computing
Tectonics and Structure
Other Applied Mathematics
Plasma and Beam Physics
OS and Networks
Statistics and Probability
Statistical Methodology
Stratigraphy
Geophysics and Seismology
Physical Sciences and Mathematics
Applied Mathematics
FOS Mathematics
Information Security
Ordinary Differential Equations and Applied Dynamics
Stars, Interstellar Medium and the Galaxy
Other Astrophysics and Astronomy
Cosmology, Relativity, and Gravity
Paleobiology
Instrumentation
Environmental Sciences
Probability
Graphics and Human Computer Interfaces
Geology
Special Functions
Mathematics
Non-linear Dynamics
Cosmochemistry
Earth Sciences
Computer Sciences
Geomorphology
Physics
External Galaxies
Design of Experiments and Sample Surveys
Applied Statistics
Fluid Dynamics
Physical Processes
Institutional and Historical
Dynamic Systems
Statistical Theory
Artificial Intelligence and Robotics
Glaciology
Databases and Information Systems
Other Physics
spellingShingle The Sun and the Solar System
Other Computer Sciences
Statistical, Nonlinear, and Soft Matter Physics
Astrophysics and Astronomy
Partial Differential Equations
Categorical Data Analysis
Other Earth Sciences
FOS Earth and related environmental sciences
Numerical Analysis and Computation
Numerical Analysis and Scientific Computing
Tectonics and Structure
Other Applied Mathematics
Plasma and Beam Physics
OS and Networks
Statistics and Probability
Statistical Methodology
Stratigraphy
Geophysics and Seismology
Physical Sciences and Mathematics
Applied Mathematics
FOS Mathematics
Information Security
Ordinary Differential Equations and Applied Dynamics
Stars, Interstellar Medium and the Galaxy
Other Astrophysics and Astronomy
Cosmology, Relativity, and Gravity
Paleobiology
Instrumentation
Environmental Sciences
Probability
Graphics and Human Computer Interfaces
Geology
Special Functions
Mathematics
Non-linear Dynamics
Cosmochemistry
Earth Sciences
Computer Sciences
Geomorphology
Physics
External Galaxies
Design of Experiments and Sample Surveys
Applied Statistics
Fluid Dynamics
Physical Processes
Institutional and Historical
Dynamic Systems
Statistical Theory
Artificial Intelligence and Robotics
Glaciology
Databases and Information Systems
Other Physics
, LMD
On the dynamical nature of Saturn’s North Polar hexagon
topic_facet The Sun and the Solar System
Other Computer Sciences
Statistical, Nonlinear, and Soft Matter Physics
Astrophysics and Astronomy
Partial Differential Equations
Categorical Data Analysis
Other Earth Sciences
FOS Earth and related environmental sciences
Numerical Analysis and Computation
Numerical Analysis and Scientific Computing
Tectonics and Structure
Other Applied Mathematics
Plasma and Beam Physics
OS and Networks
Statistics and Probability
Statistical Methodology
Stratigraphy
Geophysics and Seismology
Physical Sciences and Mathematics
Applied Mathematics
FOS Mathematics
Information Security
Ordinary Differential Equations and Applied Dynamics
Stars, Interstellar Medium and the Galaxy
Other Astrophysics and Astronomy
Cosmology, Relativity, and Gravity
Paleobiology
Instrumentation
Environmental Sciences
Probability
Graphics and Human Computer Interfaces
Geology
Special Functions
Mathematics
Non-linear Dynamics
Cosmochemistry
Earth Sciences
Computer Sciences
Geomorphology
Physics
External Galaxies
Design of Experiments and Sample Surveys
Applied Statistics
Fluid Dynamics
Physical Processes
Institutional and Historical
Dynamic Systems
Statistical Theory
Artificial Intelligence and Robotics
Glaciology
Databases and Information Systems
Other Physics
description An explanation of long-lived Saturn’s North Polar hexagonal circumpolar jetin terms of instability of the coupled system polar vortex - circumpolar jet isproposed in the framework of the rotating shallow water model, wherescarcely known vertical structure of the Saturn’s atmosphere is averaged out.The absence of a hexagonal structure at Saturn’s South Pole is explainedsimilarly. By using the latest state-of-the-art observed winds in Saturn’spolar regions a detailed linear stability analysis of the circumpolar jet isperformed (i) excluding (“jet-only” configuration), and (2) including(“jet+vortex” configuration) the north polar vortex in the system. A domainof parameters: latitude of the circumpolar jet and curvature of its azimuthalvelocity profile, where the most unstable mode of the system has azimuthalwavenumber 6, is identified. Fully nonlinear simulations are then performed,initialized either with the most unstable mode of small amplitude, or withthe random combination of unstable modes. It is shown that developingbarotropic instability of the “jet+vortex” system produces a long-livingstructure akin to the observed hexagon, which is not the case of the“jet-only” system, which was studied in this context in a number of papersin literature. The north polar vortex, thus, plays a decisive dynamical role.The influence of moist convection, which was recently suggested to be at theorigin of Saturn’s north polar vortex system in the literature, is investigatedin the framework of the model and does not alter the conclusions.
format Report
author , LMD
author_facet , LMD
author_sort , LMD
title On the dynamical nature of Saturn’s North Polar hexagon
title_short On the dynamical nature of Saturn’s North Polar hexagon
title_full On the dynamical nature of Saturn’s North Polar hexagon
title_fullStr On the dynamical nature of Saturn’s North Polar hexagon
title_full_unstemmed On the dynamical nature of Saturn’s North Polar hexagon
title_sort on the dynamical nature of saturn’s north polar hexagon
publisher Open Science Framework
publishDate 2018
url https://dx.doi.org/10.17605/osf.io/rvdmx
https://osf.io/rvdmx/
geographic South Pole
geographic_facet South Pole
genre South pole
genre_facet South pole
op_relation https://dx.doi.org/10.1016/j.icarus.2017.06.006
op_rights CC0 1.0 Universal
op_rightsnorm CC0
op_doi https://doi.org/10.17605/osf.io/rvdmx
_version_ 1766202959326085120

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