Saturn’s Seasonally Changing Atmosphere

doi:10.1017/9781316227220.010

10 - Saturn’s Seasonally Changing Atmosphere

Thermal Structure, Composition and Aerosols

Published online by Cambridge University Press: 13 December 2018

Leigh N. Fletcher ,

Thomas K. Greathouse ,

Sandrine Guerlet ,

Julianne I. Moses and

Edited by

Norbert Krupp and

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

The longevity of Cassini’s exploration of Saturn’s atmosphere (a third of a Saturnian year) means that we have been able to track the seasonal evolution of atmospheric temperatures, chemistry and cloud opacity over almost every season, from solstice to solstice and from perihelion to aphelion. Cassini has built upon the decades-long ground-based record to observe seasonal shifts in atmospheric temperature, finding a thermal response that lags behind the seasonal insolation with a lag time that increases with depth into the atmosphere, in agreement with radiative climate models. Seasonal hemispheric contrasts are perturbed at smaller scales by atmospheric circulation, such as belt/zone dynamics, the equatorial oscillations and the polar vortices. Temperature asymmetries are largest in the middle stratosphere and become insignificant near the radiative-convective boundary. Cassini has also measured southern-summertime asymmetries in atmospheric composition, including ammonia (the key species forming the topmost clouds), phosphine and para-hydrogen (both disequilibrium species) in the upper troposphere; and hydrocarbons deriving from the UV photolysis of methane in the stratosphere (principally ethane and acetylene). These chemical asymmetries are now altering in subtle ways due to (i) the changing chemical efficiencies with temperature and insolation and (ii) vertical motions associated with large-scale overturning in response to the seasonal temperature contrasts. Similarly, hemispheric contrasts in tropospheric aerosol opacity and coloration that were identified during the earliest phases of Cassini’s exploration have now reversed, suggesting an intricate link between the clouds and the temperatures. Finally, comparisons of observations between Voyager and Cassini (both observing in early northern spring, one Saturn year apart) show tantalizing suggestions of non-seasonal variability. Disentangling the competing effects of radiative balance, chemistry and dynamics in shaping the seasonal evolution of Saturn’s temperatures, clouds and composition remains the key challenge for the next generation of observations and numerical simulations.

Type: Chapter
Information: Saturn in the 21st Century , pp. 251 - 294

DOI: https://doi.org/10.1017/9781316227220.010 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2018

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References

Abbas, M. M., LeClair, A., Woodard, E. et al. (2013), Distribution of CO₂ in Saturn’s atmosphere from Cassini/CIRS infrared observations. Astrophys. J., 776 (Oct.), 73.Google Scholar

Appleby, J. F. and Hogan, J. S. (1984), Radiative-convective equilibrium models of Jupiter and Saturn. Icarus, 59(Sept.), 336–366.CrossRef Google Scholar

Armstrong, E. S., Moses, J. I., Fletcher, L. N. et al. (2014) (Nov.), The chemistry of ethene in the storm beacon region on Saturn. Page submitted of: AAS/Division for Planetary Sciences Meeting Abstracts. AAS/Division for Planetary Sciences Meeting Abstracts, vol. 46.Google Scholar

Atreya, S. K., Donahue, T. M. and Kuhn, W. R. (1977), The distribution of ammonia and its photochemical products on Jupiter. Icarus, 31, 348–355.CrossRef Google Scholar

Atreya, S. K., Donahue, T. M., Nagy, A. F. et al. (1984), Theory, measurements, and models of the upper atmosphere and ionosphere of Saturn. Pages 239–277 of: Gehrels, T., and Matthews, M. S. (eds), Saturn. Tucson: University of Arizona Press.Google Scholar

Atreya, S. K., Kuhn, W. R. and Donahue, T. M. (1980), Saturn: Tropospheric ammonia and nitrogen. Geophys. Res. Lett., 7, 474–476.Google Scholar

Atreya, S. K. and Wong, A.-S. (2005), Coupled clouds and chemistry of the giant planets: A case for multiprobes. Space Sci. Rev., 116 (Jan.), 121–136.Google Scholar

Atreya, S. K., Wong, M. H., Owen, T. C. et al. (1999), A comparison of the atmospheres of Jupiter and Saturn: deep atmospheric composition, cloud structure, vertical mixing, and origin. Plan. & Space Sci., 47, 1243–1262.Google Scholar

Baines, K. H., Momary, T. W., Roos-Serote, M. et al. (2006), North vs. south on Saturn: Discovery of a pronounced hemispherical asymmetry in Saturn’s 5-micron emission and associated deep cloud structure by Cassini/VIMS. B.A.A.S., 38, 488.Google Scholar

Barnet, C. D., Beebe, R. F. and Conrath, B. J. (1992), A seasonal radiative-dynamic model of Saturn’s troposphere. Icarus, 98, 94–107.Google Scholar

Bell, J. M.,Westlake, J. and Waite, J. H., Jr. (2011), Simulating the time-dependent response of Titan’s upper atmosphere to periods of magnetospheric forcing. Geophys. Res. Lett., 38, L06202.CrossRef Google Scholar

Bellucci, A., Sicardy, B., Drossart, P. et al. (2009), Titan solar occultation observed by Cassini/VIMS: Gas absorption and constraints on aerosol composition. Icarus, 201, 198–216.Google Scholar

Bézard, B., Drossart, P., Encrenaz, T. et al. (2001a), Benzene on the Giant Planets. Icarus, 154 (Dec.), 492–500.Google Scholar

Bézard, B., Drossart, P., Lellouch, E. et al. (1989), Detection of arsine in Saturn. Astrophys. J., 346, 509–513.Google Scholar

Bézard, B., Feuchtgruber, H., Moses, J. I. et al. (1998), Detection of methyl radicals (CH-3) on Saturn. Astron. Astrophys., 334, L41–L44.Google Scholar

Bézard, B. and Gautier, D. (1985), A seasonal climate model of the atmospheres of the giant planets at the Voyager encounter time: I. Saturn’s stratosphere. Icarus, 61, 296–310.Google Scholar

Bézard, B., Gautier, D. and Conrath, B. (1984), A seasonal model of the Saturnian upper troposphere Comparison with Voyager infrared measurements. Icarus, 60, 274–288.Google Scholar

Bézard, B., Lellouch, E., Strobel, D. et al. (2002), Carbon monoxide on Jupiter: Evidence for both internal and external sources. Icarus, 159, 95–111.Google Scholar

Bézard, B., Moses, J. I., Lacy, J. et al. (2001b) (Nov.), Detection of Ethylene (C2H4) on Jupiter and Saturn in Non-Auroral Regions. Pages 1079 ff. of: Bulletin of the American Astronomical Society.Google Scholar

Bjoraker, G. L., Larson, H. P. and Fink, U. (1981), A study of ethane on Saturn in the 3 micron region. Astrophys. J., 248, 856–862.Google Scholar

Bregman, J. D., Lester, D. F. and Rank, D. M. (1975), Observation of the nu-squared band of PH₃ in the atmosphere of Saturn. Astrophys. J., 202.Google Scholar

Briggs, F. H. and Sackett, P. D. (1989), Radio observations of Saturn as a probe of its atmosphere and cloud structure. Icarus, 80, 77–103.Google Scholar

Burgdorf, M. J., Orton, G. S., Encrenaz, T. et al. (2004), Far-infrared spectroscopy of the giant planets: measurements of ammonia and phosphine at Jupiter and Saturn and the continuum of Neptune. Advances in Space Research, 34, 2247–2250.Google Scholar

Caldwell, J. (1977), The atmosphere of Saturn: An infrared perspective. Icarus, 30(Mar.), 493–510.CrossRef Google Scholar

Caldwell, J., Gillett, F. C., Nolt, I. G. et al. (1978), Spatially resolved infrared observations of Saturn: I. Equatorial limb scans at 20 microns. Icarus, 35 (Sept.), 308–312.Google Scholar

Carlson, B. E., Caldwell, J. and Cess, R. D. (1980), A model of Saturn’s seasonal stratosphere at the time of the Voyager encounters. Journal of Atmospheric Sciences, 37 (Aug.), 1883–1885.Google Scholar

Carlson, R. W., Baines, K. H., Anderson, W. S. et al. (2012), (Oct.), Chromophores from Photolyzed Ammonia Reacting with Acetylene: Application to Jupiter’s Great Red Spot. Page #205.01 of: AAS/Division for Planetary Sciences Meeting Abstracts. AAS/Division for Planetary Sciences Meeting Abstracts, vol. 44.Google Scholar

Cavalié, T., Billebaud, F., Dobrijevic, M. et al. (2009), First observation of CO at 345 GHz in the atmosphere of Saturn with the JCMT: New constraints on its origin. Icarus, 203 (Oct.), 531–540.Google Scholar

Cavalié, T., Hartogh, P., Billebaud, F. et al. (2010), A cometary origin for CO in the stratosphere of Saturn? Astron. Astrophys, 510 (Feb.), A88.Google Scholar

Cess, R. D. and Caldwell, J. (1979), A Saturnian stratospheric seasonal climate model. Icarus, 38, 349–357.Google Scholar

Conrath, B. J., Gierasch, P. J. and Leroy, S. S. (1990), Temperature and circulation in the stratosphere of the outer planets. Icarus, 83, 255–281.Google Scholar

Conrath, B. J., Gierasch, P. J. and Ustinov, E. A. (1998), Thermal structure and para hydrogen fraction on the outer planets from Voyager IRIS measurements. Icarus, 135, 501–517.Google Scholar

Conrath, B. J. and Pirraglia, J. A. (1983), Thermal structure of Saturn from Voyager infrared measurements: Implications for atmospheric dynamics. Icarus, 53, 286–292.Google Scholar

Courtin, R., Gautier, D., Marten, A. et al. (1984), The composition of Saturn’s atmosphere at northern temperate latitudes from Voyager IRIS spectra – NH₃, PH₃, C₂H₂, C₂H₆, CH₃D, CH₄, and the Saturnian D/H isotopic ratio. Astrophys. J., 287, 899–916.Google Scholar

Davis, G. R., Griffin, M. J., Naylor, D. A. et al. (1996), ISO LWS measurement of the far-infrared spectrum of Saturn. Astron. Astrophys., 315, L393–L396.Google Scholar

de Graauw, T., Feuchtgruber, H., Bézard, B. et al. (1997), First results of ISO-SWS observations of Saturn: detection of CO₂, CH₃C₂ H, C₄H₂ and tropospheric H₂O. Astron. Astrophys., 321, L13–L16.Google Scholar

de Pater, I. and Massie, S. T. (1985), Models of the millimeter-centimeter spectra of the giant planets. Icarus, 62, 143–171.Google Scholar

Del Genio, A. D., Achterberg, R. K., Baines, K. H. et al. (2009), Saturn Atmospheric Structure and Dynamics, In: Saturn from Cassini-Huygens. Springer. Chap. 6, pages 113–159.CrossRef Google Scholar

Dobrijevic, M., Cavalié, T. and Billebaud, F. (2011), A methodology to construct a reduced chemical scheme for 2D-3D photochemical models: Application to Saturn. Icarus, 214, 275–285.Google Scholar

Dobrijevic, M., Hébrard, E., Loison, J. C. et al. (2014), Coupling of oxygen, nitrogen, and hydrocarbon species in the photochemistry of Titan’s atmosphere. Icarus, 228, 324–346.Google Scholar

Dowling, T. E., Greathouse, T. K., Sussman, M. G. et al. (2010) (Oct.), New Radiative Transfer Capability in the EPIC Atmospheric Model with Application to Saturn and Uranus. Page 1021 of: AAS/Division for Planetary Sciences Meeting Abstracts #42. Bulletin of the American Astronomical Society, vol. 42.Google Scholar

Edgington, S. G., Atreya, S. K., Trafton, L. M. et al. (1997), Phosphine mixing ratios and eddy mixing coefficients in the troposphere of Saturn. Bulletin of the American Astronomical Society, 29, 992.Google Scholar

Edgington, S. G., Atreya, S. K., Wilson, E. H. et al. (2012), Photochemistry in Saturn’s Ring Shadowed Atmosphere: Production Rates of Key Atmospheric Molecules and Preliminary Analysis of Observations. AGU Fall Meeting Abstracts, Dec., B1946.Google Scholar

Encrenaz, T., Owen, T. and Woodman, J. H. (1974), The abundance of ammonia on Jupiter, Saturn and Titan. Astron. Astrophys., 37 (Dec.), 49–55.Google Scholar

Fegley, Jr., B. and Lodders, K. (1994), Chemical models of the deep atmospheres of Jupiter and Saturn. Icarus, 110 (July), 117–154.Google Scholar

Fegley, B. and Prinn, R. G. (1985), Equilibrium and nonequilibrium chemistry of Saturn’s atmosphere: Implications for the observability of PH₃, N₂, CO, and GeH₄. Astrophys. J., 299, 1067–1078.Google Scholar

Ferris, J. P. and Ishikawa, Y. (1988), Formation of HCN and acetylene oligomers by photolysis of ammonia in the presence of acetylene: Applications to the atmospheric chemistry of Jupiter. J. Am. Chem. Soc., 110, 4306–4312.Google Scholar

Fink, U., Larson, H. P., Bjoraker, G. L. et al. (1983), The NH₃ spectrum in Saturn’s 5 micron window. ApJ, 268 (May), 880–888.Google Scholar

Flasar, F. M., Achterberg, R. K., Conrath, B. J. et al. (2005), Temperatures, winds, and composition in the Saturnian system. Science, 307, 1247–1251.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.Google Scholar

Fletcher, L. N., Achterberg, R. K., Greathouse, T. K. et al. (2010), Seasonal change on Saturn from Cassini/CIRS observations, 2004–2009. Icarus, 208 (July), 337–352.Google Scholar

Fletcher, L. N., Baines, K. H., Momary, T. W. et al. (2011), Saturn’s tropospheric composition and clouds from Cassini/VIMS 4.6–5.1 µm nightside spectroscopy. Icarus, 214 (Aug.), 510–533.Google Scholar

Fletcher, L. N., Hesman, B. E., Achterberg, R. K. et al. (2012b), The origin and evolution of Saturn’s 2011–2012 stratospheric vortex. Icarus, 221 (Nov.), 560–586.Google Scholar

Fletcher, L. N., Irwin, P. G. J., Achterberg, R. K. et al. (2016), Seasonal variability of Saturn’s tropospheric temperatures, winds and para-H₂ from Cassini Far-IR Spectroscopy. Icarus, 264, 137–159.Google Scholar

Fletcher, L. N., Irwin, P. G. J., Orton, G. S. et al. (2008), Temperature and composition of Saturn’s polar hot spots and hexagon. Science, 319 (Jan.), 79–82.Google Scholar

Fletcher, L. N., Irwin, P. G. J., Sinclair, J. A. et al. (2015), Seasonal evolution of Saturn’s polar temperatures and composition. Icarus, 131–153.Google Scholar

Fletcher, L. N., Irwin, P. G. J., Teanby, N. A. et al. (2007a), Characterising Saturn’s vertical temperature structure from Cassini/CIRS. Icarus, 189, 457–478.Google Scholar

Fletcher, L. N., Irwin, P. G. J., Teanby, N. A. (2007b), The meridional phosphine distribution in Saturn’s upper troposphere from Cassini/CIRS observations. Icarus, 188 (May), 72–88.Google Scholar

Fletcher, L. N., Irwin, P. G. J., Teanby, N. A. (2009), Phosphine on Jupiter and Saturn from Cassini/CIRS. Icarus, 202 (Aug.), 543–564.Google Scholar

Fletcher, L. N., Swinyard, B., Salji, C. et al. (2012a), Sub-millimetre spectroscopy of Saturn’s trace gases from Herschel/SPIRE. Astron. Astrophys., 539 (Mar.), A44.Google Scholar

Fouchet, T., Guerlet, S., Strobel, D. F. et al. (2008), An equatorial oscillation in Saturn’s middle atmosphere. Nature, 453(7192), 200–202.CrossRef Google Scholar PubMed

Fouchet, T., Lellouch, E. and Feuchtgruber, H. (2003), The hydrogen ortho-to-para ratio in the stratospheres of the giant planets. Icarus, 161, 127–143.Google Scholar

Fouchet, T., Moses, J. I. and Conrath, B. J. (2009), Saturn: Composition and Chemistry, In: Saturn from Cassini-Huygens, Springer, Chap. 5, pages 83 ff.Google Scholar

Friedson, A. J. and Moses, J. I. (2012), General circulation and transport in Saturn’s upper troposphere and stratosphere. Icarus, 218 (Apr.), 861–875.Google Scholar

Friedson, A. J., Wong, A.-S. and Yung, Y. L. (2002), Models for polar haze formation in Jupiter’s stratosphere. Icarus, 158, 389–400.Google Scholar

Gans, B., Boyé-Péronne, S., Broquier, M. et al. (2011), Photolysis of methane revisited at 121.6 nm and at 118.2 nm: quantum yields of the primary products, measured by mass spectrometry. Physical Chemistry Chemical Physics, 13, 8140.Google Scholar

Gezari, D. Y., Mumma, M. J., Espenak, F. et al. (1989), New features in Saturn’s atmosphere revealed by high-resolution thermal infrared images. Nature, 342, 777–780.Google Scholar

Gillett, F. C. and Forrest, W. J. (1974), The 7.5- to 13.5-MICRON spectrum of Saturn. Astrophys. J.l, 187(Jan.), L37.Google Scholar

Gillett, F. C. and Orton, G. S. (1975), Center-to-limb observations of Saturn in the thermal infrared. Astrophys. J., 195 (Jan.), L47–L49.Google Scholar

Giver, L. P. and Spinrad, H. (1966), Molecular Hydrogen Features in the Spectra of Saturn and Uranus. Icarus, 5, 586–589.Google Scholar

Gladstone, G. R., Allen, M. and Yung, Y. L. (1996), Hydrocarbon photochemistry in the upper atmosphere of Jupiter. Icarus, 119, 1–52.Google Scholar

Greathouse, T. K., Lacy, J. H., Bézard, B. et al. (2005), Meridional variations of temperature, C₂H₂ and C₂H₆ abundances in Saturn’s stratosphere at southern summer solstice. Icarus, 177, 18–31.Google Scholar

Greathouse, T. K., Lacy, J. H., Bézard, B. (2006), The first detection of propane on Saturn. Icarus, 181 (Mar.), 266–271.Google Scholar

Greathouse, T., Moses, J., Fletcher, L. et al. (2010) (May), Seasonal Temperature Variations in Saturn’s Stratosphere: Radiative Seasonal Model vs. Observations. Page 4806 of: EGU General Assembly Conference Abstracts. EGU General Assembly Conference Abstracts, vol. 12.Google Scholar

Greathouse, T. K., Strong, S., Moses, J. et al. (2008), A General Radiative Seasonal Climate Model Applied to Saturn, Uranus, and Neptune. AGU Fall Meeting Abstracts, Dec., P21B–06.Google Scholar

Grossman, A. W., Muhleman, D. O. and Berge, G. L. (1989), High-resolution microwave images of Saturn. Science, 245, 1211–1215.Google Scholar

Guerlet, S., Fouchet, T., Bézard, B. et al. (2009), Vertical and meridional distribution of ethane, acetylene and propane in Saturn’s stratosphere from CIRS/Cassini limb observations. Icarus, 203, 214–232.Google Scholar

Guerlet, S., Fouchet, T., Bézard, B. (2010), Meridional distribution of CH₃C₂ H and C₄H₂ in Saturn’s stratosphere from CIRS/Cassini limb and nadir observations. Icarus, 209 (Oct.), 682–695.Google Scholar

Guerlet, S., Fouchet, T., Bézard, B. (2011), Evolution of the equatorial oscillation in Saturn’s stratosphere between 2005 and 2010 from Cassini/CIRS limb data analysis. Geophysical Research Letters, 38 (May), 9201.Google Scholar

Guerlet, S., Fouchet, T., Vinatier, S. et al. (2015), Stratospheric benzene and hydrocarbon aerosols detected in Saturn’s auroral regions. Astronomy and Astrophysics, 580 (Aug.), A89.Google 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 (Aug.), 110–124.Google Scholar

Guillemin, J.-C., Janati, T. and Lassalle, L. (1995), Photolysis of phosphine in the presence of acetylene and propyne, gas mixtures of planetary interest. Advances in Space Research, 16, 85–92.Google Scholar

Hanel, R., Conrath, B., Flasar, F. M. et al. (1981), Infrared observations of the Saturnian system from Voyager 1. Science, 212, 192–200.Google Scholar

Hanel, R., Conrath, B., Flasar, F. M. (1982), Infrared observations of the Saturnian system from Voyager 2. Science, 215, 544–548.Google Scholar

Hanel, R. A., Conrath, B. J., Jennings, D. E. et al. (2003), Exploration of the Solar System by Infrared Remote Sensing: Second Edition. Exploration of the Solar System by Infrared Remote Sensing, by Hanel, R. A. and Conrath, B. J. and Jennings, D. E. and Samuelson, R. E.. Cambridge: Cambridge University Press, April 2003.Google Scholar

Hartogh, P., Lellouch, E., Moreno, R. et al. (2011), Direct detection of the Enceladus water torus with Herschel. Astron. Astrophys, 532 (Aug.), L2.Google Scholar

Hébrard, E., Dobrijevic, M., Loison, J. C. et al. (2013), Photochemistry of C₃H_p hydrocarbons in Titan’s stratosphere revisited. Astron. Astrophys., 552, A132.CrossRef Google Scholar

Hesman, B. E., Bjoraker, G. L., Sada, P. V. et al. (2012), Elusive Ethylene Detected in Saturn’s Northern Storm Region. Astrophys. J., 760 (Nov.), 24.Google Scholar

Hesman, B. E., Jennings, D. E., Sada, P. V. et al. (2009), Saturn’s latitudinal C₂H₂ and C₂H₆ abundance profiles from Cassini/CIRS and ground-based observations. Icarus, 202 (July), 249–259.Google Scholar

Holton, J. R. (2004), An Introduction to Dynamic Meteorology. Academic Press.Google Scholar

Howett, C. J. A., Irwin, P. G. J., Teanby, N. A. et al. (2007), Meridional variations in stratospheric acetylene and ethane in the Saturnian atmosphere as determined from Cassini/CIRS measurements. Icarus, 190(2), 556–572.Google Scholar

Hue, V., Cavalié, T., Dobrijevic, M. et al. (2015), 2D photochemical modeling of Saturn’s stratosphere. Part I: Seasonal variation of atmospheric composition without meridional transport. Icarus, 257 (Sept.), 163–184.Google Scholar

Hurley, J., Fletcher, L. N., Irwin, P. G. J. et al. (2012), Latitudinal variation of upper tropospheric NH₃ on Saturn derived from Cassini/CIRS far-infrared measurements. Plan. & Space Sci., 73 (Dec.), 347–363.Google Scholar

Ingersoll, A. P., Beebe, R. F., Conrath, B. J. et al. (1984), Structure and dynamics of Saturn’s atmosphere. Saturn. Pages 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 (Sept.), 522–535.Google Scholar

Kalogerakis, K. S., Marschall, J., Oza, A. U. et al. (2008), The coating hypothesis for ammonia ice particles in Jupiter: Labora-tory experiments and optical modeling. Icarus, 196 (July), 202–215.Google Scholar

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

Karkoschka, E. and Tomasko, M. G. (1992), Saturn’s upper troposphere 1986–1989. Icarus, 97, 161–181.Google Scholar

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

Kaye, J. A. and Strobel, D. F. (1983a), Formation and photochemistry of methylamine in Jupiter’s atmosphere. Icarus, 55, 399–419.Google Scholar

Kaye, J. A. and Strobel, D. F.(1983b), HCN formation on Jupiter: The coupled photochemistry of ammonia and acetylene. Icarus, 54, 417–433.Google Scholar

Kaye, J. A. and Strobel, D. F. (1983c), Phosphine photochemistry in Saturn’s atmosphere. Geophys. Res. Lett., 10, 957–960.Google Scholar

Kaye, J. A. and Strobel, D. F. (1984), Phosphine photochemistry in the atmosphere of Saturn. Icarus, 59 (Sept.), 314–335.Google Scholar

Keane, T. C., Yuan, F. and Ferris, J. P. (1996), Potential Jupiter atmospheric constituents: Candidates for the mass spectrometer in the Galileo atmospheric probe. Icarus, 122, 205–207.Google Scholar

Kerola, D. X., Larson, H. P. and Tomasko, M. G. (1997), Analysis of the near-IR spectrum of Saturn: A comprehensive radiative transfer model of its middle and upper troposphere. Icarus, 127, 190–212.Google Scholar

Kim, J. H., Kim, S. J., Geballe, T. R. et al. (2006), High-resolution spectroscopy of Saturn at 3 microns: CH₄, CH₃D, C₂H₂, C₂H₆, PH₃, clouds, and haze. Icarus, 185 (Dec.), 476–486.Google Scholar

Kim, S. J. and Geballe, T. R. (2005), The 2.9–4.2 micron spectrum of Saturn: Clouds and CH₄, PH₃, and NH₃. Icarus, 179, 449–458.Google Scholar

Kim, S. J., Sim, C. K., Lee, D. W. et al. (2012), The three-micron spectral feature of the Saturnian haze: Implications for the haze composition and formation process. Planet. Space Sci., 65, 122–129.Google Scholar

Krasnopolsky, V. A. (2014), Chemical composition of Titan’s atmosphere and ionosphere: Observations and the photochemical model. Icarus, 236, 83–91.Google Scholar

Lane, A. L., Hord, C. W., West, R. A. et al. (1982), Photopolarimetry from Voyager 2: Preliminary results on Saturn, Titan, and the rings. Science, 215(Jan.), 537–543.Google Scholar

Lara, L. M., Lellouch, E., González, M. et al. (2014), A time-dependent photochemical model for Titan’s atmosphere and the origin of H₂O. Astron. Astrophys., 566, A143.Google Scholar

Laraia, A. L., Ingersoll, A. P., Janssen, M. A. et al. (2013), Analysis of Saturn’s thermal emission at 2.2-cm wavelength: Spatial distribution of ammonia vapor. Icarus, 226(Sept.), 641–654.Google Scholar

Larson, H. P. (1980), Infrared spectroscopic observations of the outer planets, their satellites, and the asteroids. Annual Review of Astronomy and Astrophysics, 18, 43–75.Google Scholar

Lavvas, P., Galand, M., Yelle, R. V. et al. (2011), Energy deposition and primary chemical products in Titan’s upper atmosphere. Icarus, 213, 233–251.Google Scholar

Lebonnois, S. (2005), Benzene and aerosol production in Titan and Jupiter’s atmospheres: a sensitivity study. Planet. Space Sci., 53, 486–497.Google Scholar

Lellouch, E., Bézard, B., Fouchet, T. et al. (2001), The deuterium abundance in Jupiter and Saturn from ISO-SWS observations. Astron. Astrophys., 370, 610–622.Google Scholar

Lewis, J. S. and Fegley, M. B., Jr. (1984), Vertical distribution of disequilibrium species in Jupiter’s troposphere. Space Sci. Rev., 39(Oct.), 163–192.Google Scholar

Lewis, J. S. and Prinn, R. G. (1984), Planets and Their Atmospheres: Origin and Evolution. Orlando: Academic Press.Google Scholar

Li, L., Achterberg, R. K., Conrath, B. J. et al. (2013), Strong temporal variation over one Saturnian year: From Voyager to Cassini. Scientific Reports, 3 (Aug.).Google Scholar

Li, L., Conrath, B. J., Gierasch, P. J. et al. (2010), Saturn’s emitted power. Journal of Geophysical Research (Planets), 115 (Nov.), 11002.Google Scholar

Li, L., Jiang, X., Ingersoll, A. P. et al. (2011), Equatorial winds on Saturn and the stratospheric oscillation. Nature Geoscience, 4 (Nov.), 750–752.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. Astron. J., 90, 1136–1146.Google Scholar

Lodders, K. and Fegley, B. (2002), Atmospheric chemistry in giant planets, brown dwarfs, and low-mass dwarf stars: I. Carbon, nitrogen, and oxygen. Icarus, 155 (Feb.), 393–424.Google Scholar

Loison, J. C., Hébrard, E., Dobrijevic, M. et al. (2015), The neutral photochemistry of nitriles, amines and imines in the atmosphere of Titan. Icarus, 247 (Feb.), 218–247.Google Scholar

Mandt, K. E., Gell, D. A., Perry, M. et al. (2012), Ion densities and composition of Titan’s upper atmosphere derived from the Cassini Ion Neutral Mass Spectrometer: Analysis methods and comparison of measured ion densities to photochemical model simulations. J. Geophys. Res., 117, E10006.Google Scholar

Massie, S. T. and Hunten, D. M. (1982), Conversion of para and ortho hydrogen in the Jovian planets. Icarus, 49, 213–226.Google Scholar

Moos, H. W. and Clarke, J. T. (1979), Detection of acetylene in the Saturnian atmosphere, using the IUE satellite. Astrophys. J., 229, L107.Google Scholar

Moreno, R., Lellouch, E., Lara, L. M. et al. (2012), The abundance, vertical distribution and origin of H₂O in Titan’s atmosphere: Herschel observations and photochemical modelling. Icarus, 221, 753–767.Google Scholar

Moses, J. I., Armstrong, E. S., Fletcher, L. N. et al. (2014) (Nov.), Evolution of stratospheric chemistry in the Saturn storm beacon. Page submitted of: AAS/Division for Planetary Sciences Meeting Abstracts. AAS/Division for Planetary Sciences Meeting Abstracts, vol. 46.Google Scholar

Moses, J. I. and Greathouse, T. K. (2005), Latitudinal and seasonal models of stratospheric photochemistry on Saturn: Comparison with infrared data from IRTF/TEXES. Journal of Geophysical Research (Planets), 110 (Sept.), E09007.Google Scholar

Moses, J. I., Bézard, B., Lellouch, E. et al. (2000a), Photochemistry of Saturn’s atmosphere. I. Hydrocarbon chemistry and comparisons with ISO observations. Icarus, 143, 244–298.Google Scholar

Moses, J. I., Fouchet, T., Bézard, B. et al. (2005), Photochemistry and diffusion in Jupiter’s stratosphere: Constraints from ISO observations and comparisons with other giant planets. Journal of Geophysical Research (Planets), 110 (Aug.), E08001.Google Scholar

Moses, J. I., Lellouch, E., Bézard, B. et al. (2000b), Photochemistry of Saturn’s atmosphere. II. Effects of an influx of external oxygen. Icarus, 145 (May), 166–202.Google Scholar

Moses, J. I., Liang, M.-C., Yung, Y. L. et al. (2007) (Mar.), Two-Dimensional Photochemical Modeling of Hydrocarbon Abundances on Saturn. Page 2196 of: Lunar and Planetary Science Conference. Lunar and Planetary Science Conference, vol. 38.Google Scholar

Moses, J. I., Visscher, C., Fortney, J. J. et al. (2011), Disequilibrium carbon, oxygen, and nitrogen chemistry in the atmospheres of HD 189733b and HD 209458b. Astrophys. J., 737 (Aug.), 15.Google Scholar

Moses, J. I., Visscher, C., Keane, T. C. et al. (2010), On the abundance of non-cometary HCN on Jupiter. Faraday Discussions, 147, 103–136.Google Scholar

Nava, D. F., Payne, W. A., Marston, G. et al. (1993), The reaction of atomic hydrogen with germane: Temperature dependence of the rate constant and implications for germane photochemistry in the atmospheres of Jupiter and Saturn. J. Geophys. Res., 98, 5531–5537.Google Scholar

Noll, K. S., Geballe, T. R. and Knacke, R. F. (1989), Arsine in Saturn and Jupiter. Astrophys. J., 338, L71–L74.Google Scholar

Noll, K. S., Knacke, R. F., Geballe, T. R. et al. (1986), Detection of carbon monoxide in Saturn. ApJ Letters, 309 (Oct.), L91–L94.Google Scholar

Noll, K. S., Knacke, R. F., Geballe, T. R. (1988), Evidence for germane in Saturn. Icarus, 75, 409–422.Google Scholar

Noll, K. S. and Larson, H. P. (1990), The spectrum of Saturn from 1990–2230 cm⁻¹: abundances of AsH₃, CH₃D, CO, GeH₄, and PH₃. Icarus, 89, 168–189.Google Scholar

Noll, K. S. and Larson, H. P. (1991), The spectrum of Saturn from 1990 to 2230 cm⁻¹: Abundances of AsH₃, CH₃D, CO, GeH₄, NH₃, and PH₃. Icarus, 89(Jan.), 168–189.Google Scholar

O’Donoghue, J., Stallard, T. S., Melin, H. et al. (2013), The domination of Saturn’s low-latitude ionosphere by ring ‘rain’. Nature, 496 (Apr.), 193–195.Google Scholar

Ollivier, J. L., Billebaud, F., Drossart, P. et al. (2000), Seasonal effects in the thermal structure of Saturn’s stratosphere from infrared imaging at 10 microns. Astron. Astrophys., 356, 347–356.Google Scholar

Orton, G. S., Baines, K. H., Cruikshank, D. et al. (2009v Review of Knowledge Prior to the Cassini-Huygens Mission and Concurrent Research, In: Saturn from Cassini-Huygens. Springer. Chap. 2, pages 9–54.Google Scholar

Orton, G. S. and Ingersoll, A. P. (1980), Saturn’s atmospheric temperature structure and heat budget. Journal of Geophysical Research, 85 (Nov.), 5871–5881.Google Scholar

Orton, G. S., Moses, J. I., Fletcher, L. N. et al. (2014), Mid-infrared spectroscopy of Uranus from the Spitzer infrared spectrometer: 2. Determination of the mean composition of the upper troposphere and stratosphere. Icarus, 243 (Nov.), 471–493.CrossRef Google Scholar

Orton, G. S., Serabyn, E. and Lee, Y. T. (2000), Vertical distribution of PH₃ in Saturn from observations of its 1–0 and 3–2 rotational lines. Icarus, 146, 48–59.Google Scholar

Orton, G. S., Serabyn, E. and Lee, Y. T. (2001), Erratum, Volume 146, Number 1, pages 48–59 (2000), in the article Vertical distribution of PH₃ in Saturn from observations of its 1–0 and 3–2 rotational lines, Icarus, 149, 489–490.Google Scholar

Orton, G. S. and Yanamandra-Fisher, P. A. (2005), Saturn’s temperature field from high-resolution middle-infrared imaging. Science, 307, 696–698.Google Scholar

Orton, G. S., Yanamandra-Fisher, P. A., Fisher, B. M. et al. (2008), Semi-annual oscillations in Saturn’s low-latitude stratospheric temperatures. Nature, 453 (May), 196–198.Google Scholar

Palotai, C., Dowling, T. E. and Fletcher, L. N. (2014), 3D Modeling of interactions between Jupiter’s ammonia clouds and large anticyclones. Icarus, 232, 141–156.Google Scholar

Pérez-Hoyos, S., Sánchez-Lavega, A. and French, R. G. (2006), Short-term changes in the belt/zone structure of Saturn’s Southern Hemisphere (1996–2004). Astron. Astrophys., 460 (Dec.), 641–645.Google Scholar

Pérez-Hoyos, S., Sánchez-Lavega, A., French, R. G. et al. (2005), Saturn’s cloud structure and temporal evolution from ten years of Hubble Space Telescope images (1994–2003). Icarus, 176, 155–174.Google Scholar

Plessis, S., Carrasco, N., Dobrijevic, M. et al. (2012), Production of neutral species in Titan’s ionosphere through dissociative recombination of ions. Icarus, 219, 254–266.Google Scholar

Prangé, R., Fouchet, T., Courtin, R. et al. (2006), Latitudinal variation of Saturn photochemistry deduced from spatially-resolved ultraviolet spectra. Icarus, 180, 379–392.Google Scholar

Prinn, R. G. and Barshay, S. S. (1977), Carbon monoxide on Jupiter and implications for atmospheric convection. Science, 198, 1031–1034.Google Scholar

Prinn, R. G. and Fegley, B., Jr. (1981), Kinetic inhibition of CO and N₂ reduction in circumplanetary nebulae – Implications for satellite composition. Astrophys. J, 249 (Oct.), 308–317.Google Scholar

Prinn, R. G., Larson, H. P., Caldwell, J. J. et al. (1984), Composition and chemistry of Saturn’s atmosphere. Saturn. Tucson: University of Arizona Press, pages 88–149.Google Scholar

Prinn, R. G. and Owen, T. (1976), Chemistry and spectroscopy of the Jovian atmosphere. Pages 319–371 of: Gehrels, T., (ed.), Jupiter. Tucson: University of Arizona Press.Google Scholar

Pryor, W. R. and Hord, C. W. (1991), A study of photopolarimeter system UV absorption data on Jupiter, Saturn, Uranus, and Neptune: Implications for auroral haze formation. Icarus, 91, 161–172.Google Scholar

Rages, K. A. and Barth, E. L. (2012) (Oct.), Saturn Limb Hazes as Seen from Cassini. Page #500.05 of: AAS/Division for Planetary Sciences Meeting Abstracts. AAS/Division for Planetary Sciences Meeting Abstracts, vol. 44.Google Scholar

Rieke, G. H. (1975), The thermal radiation of Saturn and its rings. Icarus, 26 (Sept.), 37–44.Google Scholar

Roman, M. T., Banfield, D. and Gierasch, P. J. (2013), Saturn’s cloud structure inferred from Cassini ISS. Icarus, 225 (July), 93–110.Google Scholar

Sada, P. V., Bjoraker, G. L., Jennings, D. E. et al. (2005), Observations of C₂H₆ and C₂H₂ in the stratosphere of Saturn. Icarus, 173, 499–507.Google Scholar

Schinder, P. J., Flasar, F. M., Marouf, E. A. et al. (2011), Saturn’s equatorial oscillation: Evidence of descending thermal structure from Cassini radio occultations. Geophys. Res. Lett., 38 (Apr.), 8205.Google Scholar

Sinclair, J. A., Irwin, P. G. J., Fletcher, L. N. et al. (2013), Seasonal variations of temperature, acetylene and ethane in Saturn’s atmosphere from 2005 to 2010, as observed by Cassini-CIRS. Icarus, 225 (July), 257–271.Google Scholar

Sinclair, J. A., Irwin, P. G. J., Fletcher, L. N. (2014), From Voyager-IRIS to Cassini-CIRS: Interannual variability in Saturn’s stratosphere? Icarus, 233 (May), 281–292.Google Scholar

Spiga, A., Guerlet, S., Indurain, M. et al. (2014) (Nov.), An exploration of Saturn’s stratospheric dynamics through Global Climate Modeling. Page #508.09 of: AAS/Division for Planetary Sciences Meeting Abstracts. AAS/Division for Planetary Sciences Meeting Abstracts, vol. 46.Google Scholar

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

Stam, D. M., Banfield, D., Gierasch, P. J. et al. (2001), Near-IR Spectrophotometry of Saturnian Aerosols-Meridional and Vertical Distribution. Icarus, 152, 407–422.Google Scholar

Strobel, D. F. (1975), Aeronomy of the major planets: Photochemistry of ammonia and hydrocarbons. Reviews of Geophysics and Space Physics, 13, 372–382.Google Scholar

Strobel, D. F. (1977), NH₃ and PH₃ photochemistry in the Jovian atmosphere. Astrophys. J. Lett., 214, L97–L99.Google Scholar

Strobel, D. F. (1983), Photochemistry of the reducing atmospheres of Jupiter, Saturn, and Titan. International Reviews in Physical Chemistry, 3, 145–176.Google Scholar

Strobel, D. F. (2005), Photochemistry in outer solar system atmospheres. Space Science Reviews, 116, 155–170.Google Scholar

Sugiyama, K., Nakajima, K., Odaka, M. et al. (2011), Intermittent cumulonimbus activity breaking the three-layer cloud structure of Jupiter. Geophys. Res. Lett., 38, L13201.Google Scholar

Sugiyama, K., Nakajima, K., Odaka, M. (2014), Numerical simulations of Jupiter’s moist convection layer: Structure and dynamics in statistically steady states. Icarus, 229 (Feb.), 71–91.Google Scholar

Sylvestre, M., Guerlet, S., Fouchet, T. et al. (2015), Seasonal changes in Saturn’s stratosphere inferred from Cassini/CIRS limb observations. Icarus, 258 (Sept.), 224–238.Google Scholar

Tautermann, C. S., Wellenzohn, B. and Clary, D. C. (2006), Rates of the reaction C₂H₃ + H₂ → C₂H₄ + H. Molecular Physics, 104, 151–158.Google Scholar

Temma, T., Chanover, N. J., Simon-Miller, A. A. et al. (2005), Vertical structure modeling of Saturn’s equatorial region using high spectral resolution imaging. Icarus, 175, 464–489.Google Scholar

Tokunaga, A. T., Caldwell, J., Gillett, F. C. et al. (1978), Spatially resolved infrared observations of Saturn: II. The temperature enhancement at the South Pole of Saturn. Icarus, 36 (Nov.), 216–222.Google Scholar

Tokunaga, A. and Cess, R. D. (1977), A model for the temperature inversion within the atmosphere of Saturn. Icarus, 32 (Nov.), 321–327.Google Scholar

Tokunaga, A. T., Dinerstein, H. L., Lester, D. F. et al. (1980), The phosphine abundance on Saturn derived from new 10-micrometer spectra. Icarus, 42, 79–85.Google Scholar

Tokunaga, A., Knacke, R. F. and Owen, T. (1975), The detection of ethane on Saturn. Astrophys. J., 197, L77.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.Google Scholar

Tseng, W.-L. and Ip, W.-H. (2011), An assessment and test of Enceladus as an important source of Saturn’s ring atmosphere and ionosphere. Icarus, 212 (Mar.), 294–299.Google Scholar

van der Tak, F., de Pater, I., Silva, A. et al. (1999), Time Variability in the Radio Brightness Distribution of Saturn. Icarus, 142 (Nov.), 125–147.Google Scholar

Vander Auwera, J., Moazzen-Ahmadi, N. and Flaud, J.-M. (2007), Toward an Accurate Database for the 12 µm Region of the Ethane Spectrum. Astrophysical Journal, 662 (June), 750–757.Google Scholar

Vasavada, A. R., Hörst, S. M., Kennedy, M. R. et al. (2006), Cassini imaging of Saturn: Southern hemisphere winds and vortices. Journal of Geophysical Research (Planets), 111(E10), 5004.Google Scholar

Visscher, C. and Fegley, B. J. (2005), Chemical Constraints on the Water and Total Oxygen Abundances in the Deep Atmosphere of Saturn. Astrophys. J., 623, 1221–1227.Google Scholar

Visscher, C., Lodders, K. and Fegley, B., Jr. (2006), Atmospheric Chemistry in Giant Planets, Brown Dwarfs, and Low-Mass Dwarf Stars. II. Sulfur and Phosphorus. Astrophys. J. Letters, 648 (Sept.), 1181–1195.Google Scholar

Visscher, C. and Moses, J. I. (2011), Quenching of carbon monoxide and methane in the atmospheres of cool brown dwarfs and hot Jupiters. Astrophys. J., 738, 72.Google Scholar

Visscher, C., Moses, J. I. and Saslow, S. A. (2010), The deep water abundance on Jupiter: New constraints from thermochemical kinetics and diffusion modeling. Icarus, 209, 602–615.Google Scholar

Visscher, C., Sperier, A. D., Moses, J. I. et al. (2009) (Mar.), Phosphine and ammonia photochemistry in Jupiter’s troposphere. Page 1201 of: Lunar and Planetary Science Conference. Lunar and Planetary Science Conference, vol. 40.Google Scholar

Vuitton, V., Yelle, R. V. and Lavvas, P. (2009), Composition and chemistry of Titan’s thermosphere and ionosphere. Royal Society of London Philosophical Transactions Series A, 367, 729–741.Google Scholar

Vuitton, V., Yelle, R. V., Lavvas, P. et al. (2012), Rapid association reactions at low pressure: Impact on the formation of hydrocarbons on Titan. Astrophys. J., 744, 11.Google Scholar

Weidenschilling, S. J. and Lewis, J. S. (1973), Atmospheric and cloud structures of the jovian planets. Icarus, 20, 465–476.Google Scholar

Weisstein, E. W. and Serabyn, E. (1994), Detection of the 267 GHz J = 1–0 rotational transition of PH₃ in Saturn with a new fourier transfer spectrometer. Icarus, 109, 367–381.Google Scholar

Weisstein, E. W. and Serabyn, E. (1996), Submillimeter line search in Jupiter and Saturn. Icarus, 123, 23–36.Google Scholar

West, R. A., Baines, K. H., Karkoschka, E. et al. (2009), Clouds and Aerosols in Saturn’s Atmosphere, In: Saturn from Cassini-Huygens. Springer. Chap. 7, pages 161–179.Google Scholar

West, R. A. and Smith, P. H. (1991), Evidence for aggregate particles in the atmospheres of Titan and Jupiter. Icarus, 90 (Apr.), 330–333.Google Scholar

West, R. A., Strobel, D. F. and Tomasko, M. G. (1986), Clouds, aerosols, and photochemistry in the Jovian atmosphere. Icarus, 65, 161–217.Google Scholar

West, R. A., Tomasko, M. G., Smith, B. A. et al. (1982), Spatially resolved methane band photometry of Saturn: I. Absolute reflectivity and center-to-limb variations in the 6190-, 7250-, and 8900-A bands. Icarus, 51, 51–64.Google Scholar

Westlake, J. H., Waite, J. H., Jr., Mandt, K. E. et al. (2012), Titan’s ionospheric composition and structure: Photochemical modeling of Cassini INMS data. J. Geophys. Res., 117, E01003.Google Scholar

Winkelstein, P., Caldwell, J., Kim, S. J. et al. (1983), A determination of the composition of the Saturnian stratosphere using the IUE. Icarus, 54, 309–318.Google Scholar

Wong, A.-S., Lee, A. Y. T., Yung, Y. L. et al. (2000), Jupiter: Aerosol chemistry in the polar atmosphere. Astrophys. J. Lett., 534, L215–L217.Google Scholar

Wong, A.-S., Yung, Y. L. and Friedson, A. J. (2003), Benzene and haze formation in the polar atmosphere of Jupiter. Geophys. Res. Lett., 30, 1447.Google Scholar

Yung, Y. L. and DeMore, W. B. (1999), Photochemistry of Planetary Atmospheres. Oxford: Oxford University Press.Google Scholar

Yung, Y. L., Drew, W. A., Pinto, J. P. et al. (1988), Estimation of the reaction rate for the formation of CH₃O from H + H₂CO: Implications for chemistry in the solar system. Icarus, 73, 516–526.Google Scholar

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