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W2956368089 abstract "Convection in rotating spherical geometries is an important physical process in planetary and stellar systems. Using continuation methods at low Prandtl number, we find both strong equatorially asymmetric and symmetric polar nonlinear rotating waves in a model of thermal convection in thin rotating spherical shells with stress-free boundary conditions. For the symmetric waves convection is confined to high latitude in both hemispheres but is only restricted to one hemisphere close to the pole in the case of asymmetric waves. This is in contrast to what is previously known from studies in the field. These periodic flows, in which the pattern is rotating steadily in the azimuthal direction, develop a strong axisymmetric component very close to onset. Using stability analysis of periodic orbits the regions of stability are determined and the topology of the stable/unstable oscillatory flows bifurcated from the branches of rotating waves is described. By means of direct numerical simulations of these oscillatory chaotic flows, we show that these three-dimensional convective polar flows exhibit characteristics, such as force balance or mean physical properties, which are similar to flows occuring in planetary atmospheres. We show that these results may open a route to understanding unexplained features of gas giant atmospheres, in particular for the case of Jupiter. These include the observed equatorial asymmetry with a pronounced decrease at the equator (the so-called dimple), and the coherent vortices surrounding the poles recently observed by the Juno mission." @default.
W2956368089 created "2019-07-23" @default.
W2956368089 creator A5037833302 @default.
W2956368089 creator A5052683481 @default.
W2956368089 creator A5085048162 @default.
W2956368089 date "2019-07-08" @default.
W2956368089 modified "2023-09-30" @default.
W2956368089 title "Polar waves and chaotic flows in thin rotating spherical shells" @default.
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W2956368089 cites W1964108861 @default.
W2956368089 cites W1966809411 @default.
W2956368089 cites W1976693515 @default.
W2956368089 cites W1984695169 @default.
W2956368089 cites W1991647264 @default.
W2956368089 cites W1992188998 @default.
W2956368089 cites W1998742733 @default.
W2956368089 cites W2002872383 @default.
W2956368089 cites W2006214166 @default.
W2956368089 cites W2007370555 @default.
W2956368089 cites W2010589199 @default.
W2956368089 cites W2014113799 @default.
W2956368089 cites W2018072329 @default.
W2956368089 cites W2022154113 @default.
W2956368089 cites W2029135566 @default.
W2956368089 cites W2036658452 @default.
W2956368089 cites W2040235718 @default.
W2956368089 cites W2042296555 @default.
W2956368089 cites W2042944174 @default.
W2956368089 cites W2053070580 @default.
W2956368089 cites W2054486847 @default.
W2956368089 cites W2056397254 @default.
W2956368089 cites W2056408393 @default.
W2956368089 cites W2067817778 @default.
W2956368089 cites W2072537659 @default.
W2956368089 cites W2073061372 @default.
W2956368089 cites W2085765815 @default.
W2956368089 cites W2092187455 @default.
W2956368089 cites W2099743374 @default.
W2956368089 cites W2102182691 @default.
W2956368089 cites W2116455532 @default.
W2956368089 cites W2117465092 @default.
W2956368089 cites W2118662912 @default.
W2956368089 cites W2121324809 @default.
W2956368089 cites W2123643035 @default.
W2956368089 cites W2128010654 @default.
W2956368089 cites W2139080848 @default.
W2956368089 cites W2140153041 @default.
W2956368089 cites W2145970211 @default.
W2956368089 cites W2156125842 @default.
W2956368089 cites W2162315233 @default.
W2956368089 cites W2165699244 @default.
W2956368089 cites W2169933335 @default.
W2956368089 cites W2214891710 @default.
W2956368089 cites W2217256413 @default.
W2956368089 cites W2461766609 @default.
W2956368089 cites W2462889726 @default.
W2956368089 cites W2464427396 @default.
W2956368089 cites W2559180819 @default.
W2956368089 cites W2563716116 @default.
W2956368089 cites W2581688326 @default.
W2956368089 cites W2613314665 @default.
W2956368089 cites W2623434529 @default.
W2956368089 cites W2735687275 @default.
W2956368089 cites W2750399099 @default.
W2956368089 cites W2761129034 @default.
W2956368089 cites W2794138887 @default.
W2956368089 cites W2794194779 @default.
W2956368089 cites W2801613180 @default.
W2956368089 cites W2806267029 @default.
W2956368089 cites W2889798058 @default.
W2956368089 cites W2962816239 @default.
W2956368089 cites W2963906423 @default.
W2956368089 cites W3101071833 @default.
W2956368089 cites W3101575947 @default.
W2956368089 cites W3103005142 @default.
W2956368089 cites W3122513843 @default.
W2956368089 cites W4234284487 @default.
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W2956368089 doi "https://doi.org/10.1103/physrevfluids.4.074802" @default.
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