The Great Saturn Storm of 2010–2011

Kevin H. Baines: Affiliation:
University of Wisconsin, Madison
F. Michael Flasar: Affiliation:
NASA-Goddard Space Flight Center
Norbert Krupp: Affiliation:
Max-Planck-Institut für Sonnensystemforschung, Göttingen
Tom Stallard: Affiliation:
University of Leicester

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Summary

In December 2010, a major storm erupted in Saturn’s northern hemisphere near 37° planetographic latitude. This rather surprising event, occurring at an unexpected latitude and time, is the sixth “Great White Spot” (GWS) storm observed over the last century and a half. Such GWS events are extraordinary, planetary-scale atmospheric phenomena that dramatically change the typically bland appearance of the planet. Occurring while the Cassini mission was on orbit at Saturn, the Great Storm of 2010–2011 was well suited for intense scrutiny by the suite of sophisticated instruments onboard the Cassini spacecraft as well by modern instrumentation on ground-based telescopes and onboard the Hubble Space Telescope. This GWS erupted on 5 December close to the peak of a westward jet and generated a major dynamical disturbance that affected the whole latitude band from 25° to 48°N. At the upper cloud level, following the rapid growth of the bright outbreak spot, a blunt aerodynamic-shaped head formed due to interaction of the spot with the westward zonal jet, with the winds reaching velocities of 160 m s−1 along the periphery of the arc. Eastward of the head, the disturbance progressed in the following months forming a turbulent wake or tail with growing vortices, one of them a major enduring anticyclone (called AV) with a size of ~11,000 km. Lightning events were prominent and detected as outbursts and flashes at the head and along the disturbance at both optical and radio wavelengths. The activity of the head ceased after about seven months when AV reached it, leaving the cloud structure and ambient winds perturbed. The tops of the optically dense clouds of the head reached the 300-mbar altitude level (~50 km below tropopause), where a mixture of ices was detected, including (1) a component of water ice lofted over 200 km altitude from its 10-bar condensation level, (2) ammonia ice as the predominant component and (3) a component that might be ammonium hydrogen sulfide ice. The energetics of the frequency and power of lightning, as well as the estimated power generated by the latent heat released in the water-based convection to create the observed dynamical three-dimensional flows, both indicate that the power released for much of the 7-month lifetime of the storm (~1017 Watts) was a significant fraction of Saturn’s total radiated power (~2.2 1017 W). A post-storm depletion of ammonia vapour was also measured in the upper troposphere. The effects of the storm propagated into the stratosphere, forming two warm air masses at the ~0.5- to 5-mbar pressure level altitude that later merged into a so-called “beacon” because of its 80 K temperature excess relative to its surroundings. Related to the stratospheric disturbance, hydrocarbon composition excesses were found, in particular for ethylene (C2H4), in the high stratosphere at the ~0.1- to 0.5-mbar altitude level. Numerical models of the storm dynamics explain the major observed features that essentially result from two processes: (1) a huge and sustained, moist, convective storm at the water clouds (altitude level 10–12 bar, or ~250–275 km below the tropopause) and (2) the interaction of the updraft columns with the ambient winds that generates the turbulent wake consisting of vortices and waves. Model simulations of the GWS require a low vertical shear of the zonal winds and low static stability across the weather layer where the disturbance develops. Its upward propagation into the stratosphere involves Rossby waves and their breaking and energy deposition to form the beacon and induce chemical changes.

The decades-long interval between storms is probably related to the insolation cycle and the long radiative time constant of Saturn’s atmosphere, and several theories for temporarily storing energy have been proposed.

Type: Chapter
Information: Saturn in the 21st Century , pp. 377 - 416

DOI: https://doi.org/10.1017/9781316227220.013 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2018

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References

Acarreta, J. R. and A. Sánchez-Lavega, (1999), Vertical cloud structure in Saturn’s 1990 Equatorial storm. Icarus, 137, 24–33. doi:10.1006/icar.1998.6034.Google Scholar

Achterberg, R. K., Gierasch, P. J., Conrath, B. J. et al. (2014), Changes to Saturn’s zonal mean tropospheric thermal structure after the 2010–2011 northern hemisphere storm. Astrophysical Journal, 786, 92, pp 8. doi:10.1088/0004-637X/786/2/92.Google Scholar

Atreya, S. K. and Wong, A.-S. (2005), Coupled clouds and chemistry of the giant planets: A case for multiprobes. Space Science Reviews, 116, 121–136. doi:10.1007/s11214-005–1951-5.Google Scholar

Baines, K. H., Delitsky, M. L., Momary, T. et al. (2009), Storm clouds on Saturn: Lightning-induced chemistry and associated materials consistent with Cassini/VIMS spectra. Planetary and Space Sci. 57, 1650–1658. doi:10:1016/j.pss.2009.06.025Google Scholar

Baines, K., Momary, T., Fletcher, L., Showman, A., Brown, R., Buratti, B., Clark, R., Nicholson, P., Go, C. and Wesley, A. (2011), Saturn’s enigmatic “String of Pearls” and northern storm of 2010–2011: Manifestations of a common dynamical mechanism. EPSC abstracts, Vol 6., EPSC-DPS2011-1658, 2011.Google Scholar

Baines, K. H., Momary, T. W., Fletcher, L. N. et al. (2010), Saturn’s “String of Pearls” after five years: Still there, moving backwards faster in the Voyager system. Bulletin of the American Astronomical Society, 42, 1039.Google Scholar

Barnet, C. D., Westphal, J. A., Beebe, R. F. and Huber, L. F. (1992), Hubble Space Telescope observations of the 1990 equatorial disturbance on Saturn: Zonal winds and central meridian albedos. Icarus, 100, 499–511. doi:10.1016/0019–1035(92)90113-L.Google Scholar

Beebe, R. F., Barnet, C., Sada, P. V. and Murrell, A. S. (1992), The onset and growth of the 1990 equatorial disturbance on Saturn, Icarus, 95, 163–172. doi:10.1016/0019–1035(92)90035–6.Google Scholar

Bézard, B., Moses, J. I., Lacy, J. et al. (2001), Detection of ethylene (C₂H₄) on Jupiter and Saturn in non-auroral regions. Bulletin of the American Astronomical Society, 33, 1079.Google Scholar

Bjoraker, G., Hesman, B. E., Achterberg, R. K. and Romani, P. N. (2012), The evolution of hydrocarbons in Saturn’s northern storm region. Bulletin of the American Astronomical Society, 44, #403.05.Google Scholar

Brown, R. H., Baines, K. H., Bellucci, G. et al. (2004), The Cassini Visual and Infrared Mapping Spectrometer (VIMS) investigation. Space Science Reviews 115, 111–168. doi:10.1007/s11214-004–1453-x.Google Scholar

Borucki, W. J., Bar-Nun, A., Scarf, F. L., Look, A. F. and Hunt, G. E. (1982), Lightning activity on Jupiter, Icarus, 52, 492–502. doi:10.1016/0019–1035(82)90009–4.Google Scholar

Borucki, W. J. and McKay, C. P. (1987), Optical efficiencies of lightning in planetary atmospheres, Nature, 328, 509–510. doi:10.1038/328509a0.Google Scholar

Cavalié, T., Dobrijévic, M., Fletcher, L. N. et al. (2015), The photochemical response to the variation of temperature in Saturn’s 2011–2012 stratospheric vortex. Astronomy & Sstrophysics, 580, A55.CrossRef Google Scholar

Charney, J. G. and Drazin, P. G. (1961), Propagation of planetary-scale disturbances from the lower into the upper atmosphere. Journal of Geophysical Research, 66, 83–109. doi:10.1029/JZ066i001p00083.Google Scholar

Choi, D. S., Showman, A. P. and Brown, R. H. (2009), Cloud features and zonal wind measurements of Saturn’s atmosphere as observed by Cassini/VIMS. Journal of Geophysical Research, 114, E04007. doi:10.1029/2008JE003254.CrossRef Google Scholar

Clark, R. N. and 13 colleagues (2012), The surface composition of Iapetus: Mapping results from Cassini VIMS. Icarus, 218, 831–860.Google Scholar

Conrath, B. J. and Gautier, D. (2000), Saturn helium abundance: A reanalysis of Voyager measurements, Icarus, 144, 124–134. doi:10.1006/icar.1999.6265.Google Scholar

Dollfus, A. (1963), Mouvements dans l’atmosphère de Saturne en 1960. Observations coordonnées par l’Union Astronomique Internationale. Icarus, 2, 109–114. doi:10.1016/0019–1035(63)90010–1.Google Scholar

del Río-Gaztelurrutia, T., Legarreta, J., Hueso, R., Pérez-Hoyos, S. and Sánchez-lavega, A. (2010), A long-lived cyclone in Saturn’s atmosphere: Observations and models, Icarus, 209, 665–681. doi:10.1016/j.icarus.2010.04.002Google Scholar

Dowling, T. E., Fischer, A. S., Gierasch, P. J., Harrington, J., Lebeau, R. P. and Santori, C. M. (1998), The Explicit Planetary Isentropic-Coordinate (EPIC) atmospheric model. Icarus, 132, 221–238. doi:10.1006/icar.1998.5917.Google Scholar

Dyudina, U. A., Ingersoll, A. P., Ewald, S. P. et al. (2007), Lightning storms on Saturn observed by Cassini ISS and RPWS during 2004–2006. Icarus, 190, 545–555. doi:10.1016/j.icarus.2007.03.035.Google Scholar

Dyudina, U. A., Ingersoll, A. P., Ewald, S. P. (2010), Detection of visible lightning on Saturn. Geophysical Research Letters, 37, L09205. doi:10.1029/2010GL043188.CrossRef Google Scholar

Dyudina, U. A., Ingersoll, A. P., Ewald, S. P., Porco, C. C., Fischer, G. and Yair, Y. (2013), Saturn’s visible lightning, its radio emissions, and the structure of the 2009–2011 lightning storms. Icarus, 226, 1020–1037. doi:10.106/j.Icarus.2013.07.013.Google Scholar

Elachi, C., Allison, M. D., Borgarelli, L. et al. (2004), Radar: The Cassini Titan Radar Mapper. Space Science Reviews, 115, 71–110. doi:10.1007/s11214-004–1438-9.Google Scholar

Encrenaz, T., Combes, M., Zeau, Y., Vapillon, L. and Berezne, J. (1975), A tentative identification of C₂H₄ in the spectrum of Saturn. Astronomy & Astrophysics, 42, 355–356.Google Scholar

Fischer, G., Desch, M. D., Zarka, P. et al. (2006), Saturn lightning recorded by Cassini/RPWS in 2004. Icarus, 183, 135–152, doi:10.106/j.icarus.2006.02.010.Google Scholar

Fischer, G., Dyudina, U. A., Kurth, W. S. et al. (2011c), Overview of Saturn lightning observations. Pages 135–144 in: Rucker, H. O., Kurth, W. S., Louarn, P. and Fischer, G. (eds.), Planetary Radio Emissions VII. Vienna: Austrian Academy of Sciences Press.Google Scholar

Fischer, G., Gurnett, D. A., Kurth, W. S. et al. (2008), Atmospheric electricity at Saturn, Space Science Review, 137, 271–285, doi:10.1007/s11214-008–9370-z.Google Scholar

Fischer, G., Gurnett, D. A., Lecacheux, A., Macher, W. and Kurth, W. S. (2007b), Polarization measurements of Saturn electrostatic discharges with Cassini/RPWS below a frequency of 2 MHz, Journal of Geophysical Research, 112, A12308, doi:10.1029/2007JA012592.CrossRef Google Scholar

Fischer, G., Gurnett, D. A., Zarka, P., Moore, L. and Dyudina, U. A. (2011b), Peak electron densities in Saturn’s ionosphere derived from the low-frequency cutoff of Saturn lightning. Journal of Geophysical Research, 116, A04315, doi:10.1029/2010JA016187.Google Scholar

Fischer, G., Kurth, W. S., Dyudina, U. A. et al. (2007a), Analysis of a giant lightning storm. Icarus, 190, 528–544, doi:10.1016/j.icarus.2007.04.002.Google Scholar

Fischer, G., Kurth, W. S., Gurnett, D. A. et al. (2011a), A giant thunderstorm on Saturn. Nature, 475, 75–77. doi:10.1038/nature10205.Google Scholar

Fischer, G., Ye, S.-Y., Groene, J. B. et al. (2014), A possible influence of the Great White Spot on Saturn kilometric radiation periodicity. Annales Geophysicae, 32, 1463–1476. doi:10.5194/angeo-32–1463-2014.Google Scholar

Flasar, F. M., Kunde, V. G., Abbas, M. M. et al. (2004), Exploring the Saturn system in the thermal infrared: The composite infrared spectrometer. Space Science Reviews, 115, 169–297. doi:10.1007/s11214-004–1454-9.CrossRef Google Scholar

Fletcher, L. N., Greathouse, T. K., Orton, G. W. et al. (2014), The origin of nitrogen on Jupiter and Saturn from the ¹⁵N/¹⁴N ratio. Icarus, 238, 170–190. doi:10.1016/j.icarus.2014.05.007.Google Scholar

Fletcher, L. N., Hesman, B. E., Achterberg, R. K. et al. (2012), The origin and evolution of Saturn’s 2011–2012 stratospheric vortex. Icarus, 221, 560–586. doi:10.1016/j.icarus.2012.08.024.Google Scholar

Fletcher, L. N., Hesman, B. E., Irwin, P. G. et al. (2011), Thermal structure and dynamics of Saturn’s northern springtime disturbance. Science, 332, 1413–1417. doi:10.1126/science.1204774.Google Scholar

García-Melendo, E., Hueso, R., Sánchez-Lavega, A. et al. (2013), Atmospheric dynamics of Saturn’s 2010 giant storm, Nature Geoscience, 6, 525–529. doi:10.1038/NGEO1860.Google Scholar

García-Melendo, E., Pérez-Hoyos, S., Sánchez-Lavega, A. and Hueso, R. (2011), Saturn’s zonal wind profile in 2004–2009 from Cassini ISS images and its long-term variability. Icarus, 215, 62–74. doi:10.1016/j.icarus.2011.07.005.Google Scholar

García-Melendo, E. and Sánchez-Lavega, A. (2017), Shallow water simulations of Saturn’s giant storms at different latitudes. Icarus, 286, 241–260. doi:10.1016/j.icarus.2016.10.006.Google Scholar

García-Melendo, E., Sánchez-Lavega, A. and Hueso, R. (2007), Numerical models of Saturn’s long-lived anticyclones. Icarus, 191, 665–677. doi:10.1016/j.icarus.2007.05.02Google Scholar

Guerlet, S., Spiga, A., Sylvestre, M. et al. (2014), Global climate modeling of Saturn’s atmosphere. Part I: Evaluation of the radiative transfer model. Icarus, 238, 110–124. doi:10.1016/j.icarus.2014.05.010.Google Scholar

Guillot, T. (1995), Condensation of methane, ammonia, and water and the inhibition of convection in giant planets. Science, 269, 1697–1699. doi:10.1126/science.7569896.Google Scholar

Gurnett, D. A., Kurth, W. S., Kirchner, D. L. et al. (2004), The Cassini radio and plasma wave science investigation. Space Science Reviews, 114, 395–463. doi:10.1007/s11214-004–1434-0.Google Scholar

Harvey, V. L. and Hitchman, M. H. (1996), A climatology of the Aleutian high. Journal of Atmospheric Sciences, 53, 2088–2102.Google Scholar

Harvey, V. L., Pierce, R. B., Hitchman, M. H., Randall, C. E. and Fairlie, T. D. (2004), On the distribution of ozone in stratospheric anticyclones. Journal of Geophysical Research (Atmospheres), 109, 24308. doi:10.1029/2004JD004992.Google Scholar

Hesman, B. E., Bjoraker, G. L., Achterberg, R. K. et al. (2013), The Evolution of Hydrocarbon Compounds in Saturn’s Stratosphere During the 2010 Northern Storm. AGU Fall Meeting Abstracts, Dec. 2013, C2205.Google Scholar

Hesman, B. E., Bjoraker, G. L., Sada, P. V. et al. (2012), Elusive ethylene detected in Saturn’s northern storm region. The Astrophysical Journal, 760, 24–30. doi:10.1088/0004-637X/760/1/24.Google Scholar

Hueso, R., Legarreta, J., Pérez-Hoyos, S., Rojas, J. F., Sánchez-Lavega, A. and Morgado, A. (2010), The international outer planets watch atmospheres node database of giant-planet images. Planetary and Space Science, 58, 1152–1159. doi:10.1016/j.pss.2010.04.006.Google Scholar

Hueso, R., and Sánchez-Lavega, A. (2001), A three-dimensional model of moist convection for the giant planets: The Jupiter case. Icarus, 151, 257–274. doi:10.1006/icar.2000.6606.Google Scholar

Hueso, R., and Sánchez-Lavega, A. (2004), A three-dimensional model of moist convection for the giant planets II: Saturn’s water and ammonia moist convective storms. Icarus, 172, 255–271. doi:10.1016/j.icarus.2004.06.010.Google Scholar

Hurley, J., Irwin, P. G. J., Fletcher, L. N. et al. (2012), Observations of upper tropospheric acetylene on Saturn: No apparent correlation with 2000 km-sized thunderstorms. Planetary and Space Science, 65, 21–37. doi:10.1016/j.pss.2011.12.026.Google Scholar

Ingersoll, A. P., Beebe, R. F., Conrath, B. J. and Hunt, G. E. (1984), Structure and dynamics of Saturn’s atmosphere. In: Gehrels, T. and Matthews, M. S. (eds.), Saturn. Tucson, AZ: University of Arizona Press, 195–238.Google Scholar

Janssen, M. A., Ingersoll, A. P., Allison, M. D. et al. (2013), Saturn’s thermal emission at 2.2-cm wavelength as imaged by the Cassini RADAR radiometer. Icarus, 226, 522–535. doi:10.1016/j.icarus.2013.06.008.Google Scholar

Kaiser, M. L., Desch, M. D. and Connerney, J. E. P. (1984), Saturn’s ionosphere: Inferred electron densities. Journal of Geophysical Research, 89, A4, 2371–2376. doi:10.1029/JA089iA04p02371.Google Scholar

Karkoschka, E. and Tomasko, M. G. (1993), Saturn’s upper atmospheric hazes observed by the Hubble Space Telescope. Icarus, 106, 428–441. doi:10.1006/icar.1993.1183.Google Scholar

Karkoschka, E. and Tomasko, M. G. (2005), Saturn’s vertical and latitudinal cloud structure 1991–2004 from HST imaging in 30 filters. Icarus 179, 195–221. doi:10.1016/j.icarus.2005.05.016.Google Scholar

Konovalenko, A. A., Kalinichenko, N. N., Rucker, H. O. et al. (2013), Earliest recorded ground-based decameter wavelength observations of Saturn’s lightning during the giant E-storm detected by Cassini spacecraft in early 2006, Icarus, 224, 14–23. doi:10.1016/j.icarus.2012.07.024.Google Scholar

Laraia, A. L., Ingersoll, A. P., Janssen, M. A., Gulkis, S., Oyafuso, F. and Allison, M. (2013), Analysis of Saturn’s thermal emission at 2.2-cm wavelength: Spatial distribution of ammonia vapor. Icarus, 226, 641–654. DOI:10.1016/j.icarus.2013.06.017.Google Scholar

Larsen, H. R. and Stansbury, E. J. (1974), Association of lightning flashes with precipitation cores extending to height 7 km. Journal of Atmospheric and Terrestrial Physics, 36, 1547–1533.Google Scholar

Lebeau, R. P. and Dowling, T. E. (1998), EPIC simulations of time-dependent, three-dimensional vortices with application to Neptune’s great dark spot. Icarus, 132, 239–265. doi:10.1006/icar.1998.5918.Google Scholar

Legarreta, J. And Sánchez-Lavega, A. (2008), Vertical structure of Jupiter’s troposphere from nonlinear simulations of long-lived vortices, Icarus, 196, 184–201. doi:10.1016/j.icarus.2008.02.018.Google Scholar

Li, C. and Ingersoll, A. P. (2015), Moist convection in hydrogen atmospheres and the frequency of Saturn’s giant storms. Nat. Geoscience, 8, 398–403. doi:10.1038/ngeo2405Google Scholar

Li, L., Jiang, X., Trammell, H. J., Pan, Y., Hernandez, J., Conrath, B. J., Gierasch, P. J., Achterberg, R. K., Nixon, C. A., Flasar, F. M., Pérez-Hoyos, S., West, R. A., Baines, K. H. and Knowles, B. (2015), Saturn’s giant storm and global radiant energy. Geophys. Res. Lett., 42, 2144–2148. doi:10.1002/2015GL063763.Google Scholar

Lindal, G. F., Sweetnam, D. N. and Eshleman, V. R. (1985), The atmosphere of Saturn: An analysis of the Voyager radio occultation measurements. Astronomical Journal, 90, 1136–114. doi:10.1086/113820.Google Scholar

Manney, G. L., Froidevaux, L., Waters, J. W. et al. (1995), Formation of low-ozone pockets in the middle stratospheric anticyclone during winter. Journal of Geophysical Research-Atmospheres, 100, 13939–13950. doi:10.1029/95JD00372.Google Scholar

Miller, E. A., Klein, G., Juergens, D. W. et al. (1996), The visual and infrared mapping spectrometer for Cassini. In: L. Horn (ed.), Society of Photo-Optical Instrumentation Engineers (SPIE) Conference Series, 2803, 206–220.Google Scholar

Momary, T. W. and Baines, K. H. (2014), The anticyclonic eye of the storm. Evolution of Saturn’s Great Storm region and associated anticyclone as seen by Cassini/VIMS. Abstract 422.11. Proceedings of the 46th Annual Meeting of the Division of Planetary Sciences.Google Scholar

Moses, J. I., Armstrong, E. S., Fletcher, L. N., Irwin, P. G. J., Hesman, B. E. and Romani, P. N. (2015), Evolution of stratospheric chemistry in the Saturn storm beacon. Icarus 261, 149–168Google Scholar

Muñoz, O., Moreno, F., Molina, A., Grodent, D., Gérard, J. C. and Dols, V. (2004), Study of the vertical structure of Saturn’s atmosphere using HST/WFPC2 images. Icarus, 169, 413–428. doi:10.1016/j.icarus.2003.12.018.Google Scholar

Orton, G. S., Fletcher, L. N., Fouchet, T. et al. (2013), Ground-based observations of the aftermath of the 2010–2011 Great Northern Springtime Storm in Saturn (Invited), AGU Fall Meeting Abstracts, Dec., A6.Google Scholar

Pedlosky, J. (1979), Geophysical Fluid Dynamics, Springer-Verlag, New York, pp. 624.Google Scholar

Pérez-Hoyos, S. and Sánchez-Lavega, A. (2006), Solar flux in Saturn’s atmosphere: maximum penetration and heating rates in the aerosol and cloud layers, Icarus, 180, 368–378.Google Scholar

Pérez-Hoyos, S., Sánchez-Lavega, A., French, R. G. and Rojas, J. F. (2005), Saturn’s cloud structure and temporal evolution from ten years of Hubble Space Telescope images (1994–2003). Icarus, 176, 155–174. doi:10.1016/j.icarus.2005.01.014Google Scholar

Pierce, A. D. and Coroniti, S. C. (1966), A mechanism for the generation of acoustic-gravity waves during thunderstorm formation. Nature, 210, 1209–1210. doi:10.1038/2101209a0.Google Scholar

Porco, C. C., Baker, E., Barbara, J. et al. (2005), Cassini Imaging Science: Initial results on Saturn’s atmosphere, Science, 307, 1243–1247. doi:10.1126/science.1107691.Google Scholar

Porco, C. C., West, R. A., Squyres, S. et al. (2004), Cassini Imaging Science: Instrument characteristics and anticipated scientific investigations at Saturn, Space Sci. Rev., 115, 363–497.Google Scholar

Sánchez-Lavega, A. (1982), Motions in Saturn’s atmosphere: Observations before Voyager encounters. Icarus, 49, 1–16. doi:10.1016/0019–1035(82)90052–5.CrossRef Google Scholar

Sánchez-Lavega, A. (1994), Saturn’s Great White Spots, Chaos, 4, 341–353. doi:10.1063/1.166012.Google Scholar

Sánchez-Lavega, A. (2011) An Introduction to Planetary Atmospheres, Boca Raton, FL: Taylor-Francis, CRC Press, pp. 629.Google Scholar

Sánchez-Lavega, A. and Battaner, E. (1987), The nature of Saturn’s Great White Spots. Astronomy & Astrophysics, 185, 315–326.Google Scholar

Sánchez Lavega, A., Colas, F., Lecacheux, J., Laques, P., Miyazaki, I. and Parker, D. (1991), The Great White Spot and disturbances in Saturn’s equatorial atmosphere during 1990, Nature, 353, 397–401. doi:10.1038/353397a0.Google Scholar

Sánchez-Lavega, A., del Río-Gaztelurrutia, T., Delcroix, M. et al. (2012), Ground-based observations of the long-term evolution and death of Saturn’s 2010 Great White Spot. Icarus, 220, 561–576, doi:10.1016/j.icarus.2012.05.033.Google Scholar

Sánchez-Lavega, A., del Río-Gaztelurrutia, T., Hueso, R. et al. (2011) Deep winds beneath Saturn’s upper clouds from a seasonal long-lived planetary-scale storm. Nature, 475, 71–74. doi:10.1038/nature10203.Google Scholar

Sánchez-Lavega, A. and Gómez, J. M. (1996a), The south equatorial belt of Jupiter. I: Its life cycle. Icarus, 121, 1–17. doi:10.1006/icar.1996.0067.Google Scholar

Sánchez-Lavega, A., Hueso, R., Pérez-Hoyos, S., Rojas, J. F. and French, R. G. (2004) Saturn’s cloud morphology and zonal winds before the Cassini encounter. Icarus, 170, 519–523. doi:10.1016/j.icarus.2004.05.002.Google Scholar

Sánchez Lavega, A., Lecacheux, J., Colas, F. and Laques, P. (1993), Temporal behavior of cloud morphologies and motions in Saturn’s atmosphere. Journal of Geophysical Research, 98, 18857–18872. doi:10.1029/93JE01777.CrossRef Google Scholar

Sánchez Lavega, A., Lecacheux, J., Colas, F. and Laques, P. (1994), Photometry of Saturn’s 1990 equatorial disturbance. Icarus, 108, 158–168. doi:10.1006/icar.1994.1048.Google Scholar

Sánchez Lavega, A., Lecacheux, J., Gómez, J. M. et al. (1996b), Large-scale storms in Saturn’s atmosphere during 1994, Science, 271, 631–634. doi:10.1126/science.271.5249.631.Google Scholar

Sánchez-Lavega, A., Orton, G. S., Hueso, R. et al. (2008), Depth of a strong Jovian jet from a planetary-scale disturbance driven by storms, Nature, 451, 437–440. doi:10.1038/nature06533.Google Scholar

Sánchez-Lavega, A., Pérez-Hoyos, S., Rojas, J. F., Hueso, R. and French, R. G. (2003), A strong decrease in Saturn’s equatorial jet at cloud level. Nature, 423, 623–625. doi:10.1038/nature01653.Google Scholar

Sánchez-Lavega, A., Rojas, J. F. and Sada, P. V. (2000), Saturn’s zonal winds at cloud level, Icarus, 147, 405–420.Google Scholar

Sanz-Requena, J. F., Pérez-Hoyos, S., Sánchez-Lavega, A. et al. (2012), Cloud structure of Saturn’s 2010 storm from ground-based imaging. Icarus, 219, 142–149. doi:10.1016/j.icarus.2012.02.023.Google Scholar

Sayanagi, K. M., Dyudina, U. A., Ewald, S. P. et al. (2013), Dynamics of Saturn’s great storm of 2010–2011 from Cassini ISS and RPWS. Icarus, 223, 460–478. doi:10.1016/j.icarus.2012.12.013.Google Scholar

Sayanagi, K. S., Dyudina, U. A., Ewald, S. P., Muro, G. D. and Ingersoll, A. P. (2014), Cassini ISS observation of Saturn’s String of Pearls. Icarus, 229, 170–180. doi:10.1016/j.icarus.2013.10.032.Google Scholar

Sayanagi, K. M., Morales-Juberias, R. and Ingersoll, A. P. (2010), Saturn’s northern hemisphere ribbon: Simulations and comparison with the meandering gulf stream. Journal of the Atmospheric Sciences, 67, 2658–2678. doi:10.1175/2010JAS3315.1.Google Scholar

Shemansky, D. and Liu, X. (2012), Saturn upper atmospheric structure from Cassini EUV and FUV occultations. Canadian Journal of Physics, 90, 817–831. doi:10.1139/p2012-036.Google Scholar

Showman, A. (2007) Numerical simulations of forced shallow-water turbulence: Effects of moist convection on the large-scale circulation of Jupiter and Saturn. Journal of the Atmospheric Sciences, 64, 3132–3157. doi:10.1175/JAS4007.1.Google Scholar

Simon-Miller, A. A., Chanover, N. J., Orton, G. S., Sussman, M., Tsavaris, I. G. and Karkoschka, E. (2006), Jupiter’s White Oval turns red. Icarus, 185, 558–562. doi:10.1016/j.icarus.2006.08.002.Google Scholar

Sromovsky, L. A., Baines, K. H. and Fry, P. (2013), Saturn’s Great Storm of 2010–2011: Evidence for ammonia and water ices from analysis of VIMS spectra. Icarus, 226, 402–418. doi:10.1016/j.icarus.2013.05.043.Google Scholar

Sromovsky, L. A., Baines, K. H. and Fry, P. M. (2014), Vertical structure of Saturn lightning storms and storm-related dark ovals. American Astronomical Society, #46, #511.09.Google Scholar

Sugiyama, K., Nakajima, K., Odaka, M., Ishiwatari, M., Kuramoto, K., Morikawa, Y., Nishizawa, S., Takahashi, Y. O. and Hayashi, Y.-Y. (2011), Intermittent cumulonimbus activity breaking the three-layer cloud structure of Jupiter. Geophys. Res. Lett., 38, L13201; doi:10.1029/2011GL047878.UnlinkedGoogle Scholar

Sugiyama, K., Nakajima, K., Odaka, M., Kuramoto, K. and Hayashi, Y.-Y. (2014), Numerical simulations of Jupiter’s moist convection layer: Structure and dynamics in statistically steady states, Icarus, 229, 71–91. doi:10.1016/j.icarus.2013.10.016.Google Scholar

Tomasko, M. G. and Doose, L. R. (1984), Polarimetry and photometry of Saturn from Pioneer 11 Observations and constraints on the distribution and properties of cloud and aerosol particles, Icarus, 58, 1–34. doi:10.1016/0019–1035(84)90096–4.Google Scholar

Vallis, G. K. (2006), Atmospheric and Ocean Fluid Dynamics, Cambridge: Cambridge University Press, 745.Google Scholar

Vasavada, A. R., Hörst, S. M., Kennedy, M. R. et al. (2005), Cassini imaging of Saturn: Southern hemisphere winds and vortices. Journal of Geophysical Research. 111, E05004. doi:10.1029/2005JE002563.Google Scholar

Vasavada, A. R. and Showman, A. P. (2005), Jovian atmospheric dynamics: an update after Galileo and Cassini, Reports on Progress in Physics, 68, 1935–1996. doi:10.1088/0034–4885/68/8/R06.Google Scholar

Warwick, J. W., Pearce, J. B., Evans, D. R. et al. (1981), Planetary radio astronomy observations from Voyager 1 near Saturn. Science, 212, 239–243. doi:10.1126/science.212.4491.239.Google Scholar

West, R. A., Baines, K. H., Karkoschka, E. and Sánchez-Lavega, A. (2009), Clouds and aerosols in Saturn’s atmosphere. Pages 113–159 in: Dougherty, M. K., Esposito, L. W. and Krimigis, S. M. (eds.), Saturn from Cassini–Huygens. New York, NY: Springer.Google Scholar

Westphal, J. A., Baum, W. A., Ingersoll, A. P. et al. (1992), Hubble Space Telescope observations of the 1990 equatorial disturbance on Saturn: Images, albedos and limb darkening. Icarus, 100, 485–498. doi:10.1016/0019–1035(92)90112-K.Google Scholar

Zakharenko, V., Mylostna, C., Konovalenko, A. et al. (2012), Ground-based and spacecraft observations of lightning activity on Saturn. Planetary and Space Science, 61, 53–59. doi:10.1016/j.pss.2011.07.021.Google Scholar

Zarka, P., Cecconi, B., Denis, L. et al. (2006), Physical properties and detection of Saturn’s lightning radio bursts. Pages 111–122 in: Planetary Radio Emissions VI, Rucker, H. O., Kurth, W. S. and Mann, G. (eds.), Vienna: Austrian Academy of Sciences Press.Google Scholar

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13 - The Great Saturn Storm of 2010–2011

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