论文信息 - The long‐term steady motion of Saturn's hexagon and the stability of its enclosed jet stream under seasonal changes - 字舞流文

The long‐term steady motion of Saturn's hexagon and the stability of its enclosed jet stream under seasonal changes

We investigate the long-term motion of Saturn's north pole hexagon and the structure of its associated eastward jet, using Cassini imaging science system and ground-based images from 2008 to 2014. We show that both are persistent features that have survived the long polar night, the jet profile remaining essentially unchanged. During those years, the hexagon vertices showed a steady rotation period of 10 h 39 min 23.01 ± 0.01 s. The analysis of Voyager 1 and 2 (1980–1981) and Hubble Space Telescope and ground-based (1990–1991) images shows a period shorter by 3.5 s due to the presence at the time of a large anticyclone. We interpret the hexagon as a manifestation of a vertically trapped Rossby wave on the polar jet and, because of their survival and unchanged properties under the strong seasonal variations in insolation, we propose that both hexagon and jet are deep-rooted atmospheric features that could reveal the true rotation of the planet Saturn.

I. Mendikoa | Agustin Sanchez-Lavega | Ricardo Hueso | Santiago Pérez-Hoyos | T. del Río-Gaztelurrutia | J. F. Rojas | Enrique Garcia-Melendo | R. Hueso | D. Peach | E. García‐Melendo | A. Sánchez‐Lavega | S. Pérez-Hoyos | I. Mendikoa | J. Gomez-Forrellad | C. Go | A. Antuñano | D. Peach | A. Wesley | Christopher Y. Go | J. Lillo | D. Barrado-Navascués | Josep M. Gomez-Forrellad | T. Barry | A. Wesley | Arrate Antuñano | D. P. Milika | P. Nicholas | T. Barry | D. Barrado-Navascués | S. P'erez-Hoyos | E. Garc'ia-Melendo | T. Río‐Gaztelurrutia | Iopw Team | J. Lillo | P. Nicholas | A. S'anchez-Lavega | A. Antunano | Centro Astronómico | Hispano Alemán

[1] M. L. Kaiser,et al. Voyager measurement of the rotation period of Saturn's magnetic field , 1981 .

[2] Agustín Sánchez-Lavega,et al. How Long Is the Day on Saturn? , 2005, Science.

[3] Javier Peralta,et al. The Planetary Laboratory for Image Analysis (PLIA) , 2010 .

[4] R. Hueso,et al. Deep winds beneath Saturn’s upper clouds from a seasonal long-lived planetary-scale storm , 2011, Nature.

[5] A. Ingersoll,et al. Emergence of polar-jet polygons from jet instabilities in a Saturn model , 2011 .

[6] G. F. Lindal,et al. The atmosphere of Saturn - an analysis of the Voyager radio occultation measurements , 1985 .

[7] A. Sánchez-Lavega,et al. Saturn’s zonal wind profile in 2004–2009 from Cassini ISS images and its long-term variability , 2011 .

[8] R. Hueso,et al. The jovian anticyclone BA: II. Circulation and interaction with the zonal jets , 2009 .

[9] Stefan Hippler,et al. AstraLux - the Calar Alto 2.2-m telescope Lucky Imaging Camera , 2008, 0807.0504.

[10] S. Pérez-Hoyos,et al. Solar flux in Saturn's atmosphere: Penetration and heating rates in the aerosol and cloud layers , 2006 .

[11] Donald A. Gurnett,et al. The reversal of the rotational modulation rates of the north and south components of Saturn kilometric radiation near equinox , 2010 .

[12] J. F. Rojas,et al. New Observations and Studies of Saturn's Long-Lived North Polar Spot , 1997 .

[13] M. Allison,et al. A Wave Dynamical Interpretation of Saturn's Polar Hexagon , 1987, Science.

[14] J. Anderson,et al. Saturn's Gravitational Field, Internal Rotation, and Interior Structure , 2007, Science.

[15] B. Bézard,et al. A seasonal model of the Saturnian upper troposphere: Comparison with Voyager infrared measurements , 1983 .

[16] P. Read,et al. A laboratory model of Saturn's North Polar hexagon , 2010 .

[17] R. Clark,et al. Saturn's north polar cyclone and hexagon at depth revealed by Cassini/VIMS , 2009 .

[18] G. Orton,et al. Temperature and Composition of Saturn's Polar Hot Spots and Hexagon , 2008, Science.

[19] P. Gierasch,et al. Mapping potential vorticity dynamics on saturn: Zonal mean circulation from Cassini and Voyager data , 2009 .

[20] Ricardo Hueso,et al. The international outer planets watch atmospheres node database of giant-planet images , 2010 .

[21] R. Hueso,et al. Atmospheric dynamics of Saturn/'s 2010 giant storm , 2013 .

[22] G. Orton,et al. Seasonal change on Saturn from Cassini/CIRS observations, 2004–2009 , 2010 .

[23] Agustin Sanchez-Lavega,et al. PlanetCam UPV/EHU: a simultaneous visible and near infrared lucky-imaging camera to study solar system objects , 2012, Other Conferences.

[24] A. Ingersoll,et al. Motion in the interiors and atmospheres of Jupiter and Saturn: scale analysis, anelastic equations, barotropic stability criterion , 1982 .

[25] R. Hueso,et al. Numerical models of Saturn's long-lived anticyclones , 2007 .

[26] Robert M. Gray,et al. An Algorithm for Vector Quantizer Design , 1980, IEEE Trans. Commun..

[27] D. Tholen,et al. Report of the IAU/IAG Working Group on cartographic coordinates and rotational elements: 2006 , 2007 .

[28] D. Godfrey,et al. A hexagonal feature around Saturn's north pole , 1988 .

[29] J. F. Rojas,et al. Saturn's Zonal Winds at Cloud Level , 1999 .

[30] R. Gray,et al. Vector quantization , 1984, IEEE ASSP Magazine.

[31] J. Burns,et al. Cassini Imaging Science: Instrument Characteristics And Anticipated Scientific Investigations At Saturn , 2004 .

[32] L. Rabiner,et al. The acoustics, speech, and signal processing society - A historical perspective , 1984, IEEE ASSP Magazine.

[33] Cambridge,et al. Lucky imaging: High angular resolution imaging in the visible from the ground , 2005, astro-ph/0507299.

[34] C. Barnet,et al. The Drift of Saturn's North Polar Spot Observed by the Hubble Space Telescope , 1993, Science.

[35] D. Godfrey. The Rotation Period of Saturn's Polar Hexagon , 1990, Science.

[36] G. Schubert,et al. Saturn’s rotation period from its atmospheric planetary-wave configuration , 2009, Nature.

[37] J. Lecacheux,et al. Ground-Based Observations of Saturn's North Polar Spot and Hexagon , 1993, Science.