Abstract
Jupiter's atmosphere, as observed in the 1979 Voyager space craft images, is characterized by 12 zonal jet streams and about 80 vortices, the largest of which are the Great Red Spot and three White Ovals that had formed1 in the 1930s. The Great Red Spot has been observed2 continuously since 1665 and, given the dynamical similarities between the Great Red Spot and the White Ovals, the disappearance3,4 of two White Ovals in 1997–2000 was unexpected. Their longevity and sudden demise has been explained5 however, by the trapping of anticyclonic vortices in the troughs of Rossby waves, forcing them to merge. Here I propose that the disappearance of the White Ovals was not an isolated event, but part of a recurring climate cycle which will cause most of Jupiter's vortices to disappear within the next decade. In my numerical simulations, the loss of the vortices results in a global temperature change of about 10 K, which destabilizes the atmosphere and thereby leads to the formation of new vortices. After formation, the large vortices are eroded by turbulence over a time of ∼60 years—consistent with observations of the White Ovals—until they disappear and the cycle begins again.
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Acknowledgements
The author thanks T. Kundu for cloud simulations and X. Asay-Davis, S. Shetty and C.-H. Jiang for calculations of temperature changes. The work was supported by the NASA Origins Program, the NSF Astronomy and Plasma Physics Programs and LANL. Computing resources were supplied by NPACI (supported by the NSF).
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Supplementary Movie
Figure 3 of the Letter shows stills from this movie, which is a numerical simulation of two anticyclonic White Ovals (red) and a small intervening cyclone (blue) trapped in the trough of a Rossby wave. (MOV 882 kb)
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Marcus, P. Prediction of a global climate change on Jupiter. Nature 428, 828–831 (2004). https://doi.org/10.1038/nature02470
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DOI: https://doi.org/10.1038/nature02470
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