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Seeking Europa's Ocean

Published online by Cambridge University Press:  03 November 2010

Robert T. Pappalardo*
Affiliation:
Jet Propulsion Laboratory, California Institute of Technology email: [email protected]
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Abstract

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Galileo spacecraft data suggest that a global ocean exists beneath the frozen ice surface Jupiter's moon Europa. Since the early 1970s, planetary scientists have used theoretical and observational arguments to deliberate the existence of an ocean within Europa and other large icy satellites. Galileo magnetometry data indicates an induced magnetic field at Europa, implying a salt water ocean. A paucity of large craters argues for a surface on average only ~40-90 Myr old. Two multi-ring structures suggest that impacts punched through an ice shell ~20 km thick. Europa's ocean and surface are inherently linked through tidal deformation of the floating ice shell, and tidal flexing and nonsynchronous rotation generate stresses that fracture and deform the surface to create ridges and bands. Dark spots, domes, and chaos terrain are probably related to tidally driven ice convection along with partial melting within the ice shell. Europa's geological activity and probable mantle contact permit the chemical ingredients necessary for life to be present within the satellite's ocean. Astonishing geology and high astrobiological potential make Europa a top priority for future spacecraft exploration, with a primary goal of assessing its habitability.

Type
Contributed Papers
Copyright
Copyright © International Astronomical Union 2010

References

Alexander, C., Carlson, R., Consolmagno, G., Greeley, R., & Morrison, D. 2009, The exploration history of Europa Europa, Pappalardo, R. T. et al. , eds., pp. 3–26. Univ. of Arizona Press, TucsonCrossRefGoogle Scholar
Aydin, A. 2006, Failure modes of the lineaments on Jupiter's moon, Europa: Implications for the evolution of its icy crust, J. Struct. Geol., 28, 22222236CrossRefGoogle Scholar
Barr, A. C., Nimmo, F., Pappalardo, R. T., & Gaidos, E. 2002, Shear heating and solid-state convection: Implications for astrobiology, Lunar Planet. Sci. Conf. XXXIII, abstract #1545Google Scholar
Barr, A. C. & Showman, A. P. 2009, Heat transfer in Europa's icy shell, Europa, Pappalardo, R. T. et al. , eds., pp. 405430. Univ. of Arizona Press, TucsonGoogle Scholar
Blankenship, D. D., Young, D. A., Moore, W. B., & Moore, J. C. 2009, Radar sounding of Europa's subsurface properties and processes: The view from Earth, Europa, Pappalardo, R. T. et al. , eds., pp. 631654. Univ. of Arizona Press, TucsonGoogle Scholar
Bierhaus, E. B., Zahnle, K., & Chapman, C. R. 2009, Europa's crater distributions and surface ages, Europa, Pappalardo, R. T. et al. , eds., pp. 161180. Univ. of Arizona Press, TucsonGoogle Scholar
Carlson, R. W., Calvin, W. M., Dalton, J. B., Hansen, G. B., Hudson, R. L., Johnson, R. E., McCord, T. B., & Moore, M. H. 2009, Europa's surface composition, Europa, Pappalardo, R. T. et al. , eds., pp. 283328. Univ. of Arizona Press, TucsonGoogle Scholar
Carr, M. H., Belton, M. J. S., Chapman, C. R., Davies, M. E., Geissler, P., Greenberg, R., McEwen, A. S., Greeley, R., Sullivan, R., Head, J. W., Pappalardo, R. T., Klaasen, K. P., Johnson, T. V., Moore, J., Neukum, G., Schubert, G., Burns, J. A., Thomas, P., & Veverka, J. 1998, Evidence for a subsurface ocean on Europa, Nature, 391, 363365CrossRefGoogle ScholarPubMed
Cassen, P. M., Peale, S. J., & Reynolds, R. T. 1982, Structure and thermal evolution of the Galilean satellites, Satellites of Jupiter, Morrison, D., ed., pp. 931128, Univ. of Ariz. Press, TucsonGoogle Scholar
Collins, G. & Nimmo, F. 2009, Chaos on Europa, Europa, Pappalardo, R. T. et al. , eds., pp. 259282. Univ. of Arizona Press, TucsonGoogle Scholar
Collins, G. C., Head, J. W., Pappalardo, R. T., & Spaun, N. A. 2000, Evaluation of models for the formation of chaotic terrain on Europa, J. Geophys. Res., 105, 17091716CrossRefGoogle Scholar
Consolmagno, G. J. & Lewis, J. S. 1976, Structural and thermal models of icy Galilean satellites, Jupiter, (Gehrels, T. A., ed.), pp. 10351051. Univ. of Arizona, TucsonGoogle Scholar
Dalton, J. B. 2007, Linear mixture modeling of Europa's nonice material using cryogenic laboratory spectroscopy, Geophys. Res. Lett. 34, L21205, doi: 10.1029/2007GL031497CrossRefGoogle Scholar
Fanale, F. P., Johnson, T. V., & Matson, D. L., 1977, Io's surface and the histories of the Galilean satellites, Planetary Satellites, (Burns, J. A., ed.), pp. 379405. Univ. of Arizona, TucsonGoogle Scholar
Greeley, R., Pappalardo, R. T., Prockter, L. M., & Hendrix, A. 2009, Future exploration of Europa, Europa, (Burns, J. A., ed.), (Pappalardo, R. T. et al. , eds.), pp. 655695, Univ. of Arizona, TucsonGoogle Scholar
Greenberg, R. & Weidenschilling, S. J. 1984, How fast do Galilean satellites spin?, Icarus, 58, 186196CrossRefGoogle Scholar
Greenberg, R., Hoppa, G. V., Tufts, B. R., Geissler, P., Riley, J., & Kadel, S. 1999, Chaos on Europa, Icarus, 141, 263286CrossRefGoogle Scholar
Greenberg, R., Geissler, P., Tufts, B. R., & Hoppa, G. V. 2000, Habitability of Europa's crust: The role of tidal-tectonic processes, J. Geophys. Res., 105, 17, 551–17, 562CrossRefGoogle Scholar
Greenberg, R., Geissler, P., Hoppa, G., & Tufts, B. R. 2002, Tidal tectonic processes and their implications for the character of Europa's icy crust, Rev. Geophysics 40, 1004, doi:10.1029/2000RG000096CrossRefGoogle Scholar
Hand, K. P., Carlson, R. W., & Chyba, C. F. 2007, Energy, chemical disequilibrium, and geological constraints on Europa, Astrobiology, 7, 118CrossRefGoogle ScholarPubMed
Hand, K. P., Chyba, C. F., Priscu, J. C., Carlson, R. W., & Nealson, K. H. 2009, Astrobiology and the potential for life on Europa, Europa, Pappalardo, R. T. et al. , eds., pp. 589630. Univ. of Arizona Press, TucsonGoogle Scholar
Hoppa, G. V., Tufts, B. R., Greenberg, R., & Geissler, P. E. 1999, Formation of cycloidal features on Europa, Science, 285, 18991902CrossRefGoogle ScholarPubMed
Hussman, H., Spohn, T., & Wieczerkowski, K. 2002, Thermal equilibrium states of Europa's ice shell: Implications for internal ocean thickness and surface heat flow, Icarus, 156, 143151CrossRefGoogle Scholar
Johnson, R. E., Burger, M. H., Cassidy, T. A., Leblanc, F., Marconi, M., & Smyth, W. H. 2009, Composition and detection of Europa's sputter-induced atmosphere, Europa, Pappalardo, R. T. et al. , eds., pp. 507528. Univ. of Arizona Press, TucsonGoogle Scholar
Kattenhorn, S. A. & Hurford, T. 2009, Tectonics of Europa, Europa, Pappalardo, R. T. et al. , eds., pp. 199236. Univ. of Arizona Press, TucsonGoogle Scholar
Khurana, K. K., Kivelson, M. G., Hand, K. P., & Russell, C. T. 2009, Electromagnetic induction from Europa's ocean and the deep interior, Europa, Pappalardo, R. T. et al. , eds., pp. 571587. Univ. of Arizona Press, TucsonGoogle Scholar
Kivelson, M. G., Khurana, K. K., Stevenson, D. J., Bennett, L., Joy, S., Russell, C. T., Walker, R. J., Zimmer, C., & Polansky, C. 1999, Europa and Callisto: Induced or intrinsic fields in a periodically varying plasma environment, J. Geophys. Res., 104 46094625Google Scholar
Kivelson, M. G., Khurana, K. K., Russell, C. T., Volwerk, M., Walker, R. J., & Zimmer, C. 2000, Galileo magnetometer measurements strengthen the case for a subsurface ocean at Europa, Science, 289, 1340CrossRefGoogle ScholarPubMed
Kivelson, M. G., Khurana, K. K., & Volwerk, M. 2002, The permanent and inductive magnetic moments of Ganymede, Icarus, 157, 507522CrossRefGoogle Scholar
Lucchitta, B. K. & Soderblom, L. A. 1982, The geology of Europa, The Satellites of Jupiter, (Morrison, D., ed.), pp. 521555. Univ. of Arizona, Tucson, ArizonaGoogle Scholar
Malin, M. C. & Pieri, D. C. 1986, Europa, Satellites, (Burns, J. A. and Matthews, M. S., Eds.), pp. 689716. Univ. of Arizona Press, TucsonCrossRefGoogle Scholar
McCollom, T. M. 1999, Methanogenesis as a potential source of chemical energy for primary biomass production by autotrophic organisms in hydrothermal systems on Europa, J. Geophys. Res, 104, 3072930742CrossRefGoogle Scholar
McCord, T. B., Hansen, G. B., Matson, D. L., Johnson, T. V., Crowley, J. K., Fanale, F. P., Carlson, R. W., Smythe, W. D., Martin, P. D., Hibbitts, C. A., Granahan, J. C., Ocampo, A., & the NMS Team 1999, Hydrated salt minerals on Europa's surface from the Galileo NIMS investigation, J. Geophys. Res, 104, 1182711851CrossRefGoogle Scholar
McKinnon, W. B. 1999, Convective instability in Europa's floating ice shell, Geophys. Res. Lett, 26, 951954CrossRefGoogle Scholar
McKinnon, W. B., Pappalardo, R. T., & Khurana, K. K. 2009, Europa: Perspectives on an ocean world, Europa, (Pappalardo, R. T. et al. , eds.), pp. 697709, Univ. of Arizona, TucsonGoogle Scholar
Moore, W. B. & Schubert, G. 2000, The tidal response of Europa, Icarus, 147, 317319CrossRefGoogle Scholar
Moore, W. B. & Hussman, H. 2009, Thermal evolution of Europa's silicate interior, Europa, Pappalardo, R. T. et al. , eds., pp. 369380. Univ. of Arizona Press, TucsonGoogle Scholar
Moore, J. M., Asphaug, E., Sullivan, R. J., Klemaszewski, J. E., Bender, K. C., Greeley, R., Geissler, P. E., McEwen, A. S., Turtle, E. P., Phillips, C. B., Tufts, B. R., Head, J. W., Pappalardo, R. T., Jones, K. B., Chapman, C. R., Belton, M. J. S., Kirk, R. L., & Morrison, D. 1998, Large impact features on Europa: Results of the Galileo nominal mission, Icarus, 135, 127145CrossRefGoogle Scholar
Moore, J. M., Asphaug, E. B., Michael, J. S., Bierhaus, B., Breneman, H. H., Brooks, S. M., Chapman, C. R., Chuang, F. C., Collins, G. C., Giese, B., Greeley, R., Head, J. W., Kadel, S., Klaasen, K. P., Klemaszewski, J. E., Magee, K. P., Moreau, J., Morrison, D., Neukum, G., Pappalardo, R. T., Phillips, C. B., Schenk, P. M., Senske, D. A., Sullivan, R. J., Turtle, E. P., & Williams, K. K. 2001, Impact features on Europa: Results of the Galileo Europa Mission (GEM)., Icarus, 151, 93111CrossRefGoogle Scholar
Nimmo, F. & Gaidos, E. 2002, Strike-slip motion and double ridge formation on Europa, J. Geophys. Res., 107, 18Google Scholar
Nimmo, F. & Manga, M. 2009, Geodynamics of Europa's icy shell, Europa, (Pappalardo, R. T. et al. , eds.), pp. 381404, Univ. of Arizona, TucsonGoogle Scholar
Ojakangas, G. W. & Stevenson, D. J. 1989, Thermal state of an ice shell on Europa, Icarus, 81, 220241CrossRefGoogle Scholar
Pappalardo, R. T. & Barr, A. C. 2004, Origin of domes on Europa: The role of thermally induced compositional buoyancy, Geophys. Res. Lett., 31, L01701, doi:10.1029/2003GL019202CrossRefGoogle Scholar
Pappalardo, R. T. & Sullivan, R. J. 1996, Evidence for separation across a gray band on Europa, Icarus, 123, 557567CrossRefGoogle Scholar
Pappalardo, R. T., Head, J. W., Greeley, R., Sullivan, R. J., Pilcher, C., Schubert, G., Moore, W., Carr, M. H, Moore, J. M., Belton, M. J. S., & Goldsby, D. L. 1998, Geological evidence for solid-state convection in Europa's ice shell, Nature, 391, 365368CrossRefGoogle ScholarPubMed
Paranicas, C., Cooper, J. F., Garrett, H. B., Johnson, R. E., & Sturner, S. J. 2009, Europa's radiation environment and its effects on the surface, Europa, Pappalardo, R. T. et al. , eds., pp. 529544. Univ. of Arizona Press, TucsonGoogle Scholar
Prockter, L. M. & Pappalardo, R. T. 2000, Folds on Europa: Implications for crustal cycling and accommodation of extension, Science, 289, 941943CrossRefGoogle ScholarPubMed
Prockter, L. M. & Patterson, G. W. 2009, Morphology and evolution of Europa's ridges and bands, Europa, (Pappalardo, R. T. et al. , eds.), pp. 237258, Univ. of Arizona, TucsonGoogle Scholar
Prockter, L. M., Head, J., Pappalardo, R., Sullivan, R., Clifton, A. E., Giese, B., Wagner, R., & Neukum, G. 2002, Morphology of europan bands at high resolution: A mid-ocean ridge-type rift mechanism, J. Geophys. Res., 107, 126Google Scholar
Reynolds, R. T. & Cassen, P. 1979, On the internal structure of the major satellites of the outer planets, Geophys. Res. Lett., 6, 121124CrossRefGoogle Scholar
Schenk, P. M. 2002, Thickness constraints on the icy shells of the Galilean satellites from a comparison of crater shapes, Nature, 417, 419421CrossRefGoogle ScholarPubMed
Schenk, P. & McKinnon, W. B. 1989, Fault offsets and lateral crustal movement on Europa: Evidence for a mobile ice shell, Icarus, 79, 75100CrossRefGoogle Scholar
Schenk, P. M. & Turtle, E. P. 2009, Europa's impact craters: Probes of the icy shell, Europa, Pappalardo, R. T. et al. , eds., pp. 181198. Univ. of Arizona Press, TucsonGoogle Scholar
Schenk, P., Matsuyama, I., & Nimmo, F. 2008, True polar wander on Europa from global-scale small-circle depressions, Nature, 453, 368371CrossRefGoogle ScholarPubMed
Schubert, G., Sohl, F., & Hussman, H. 2009, Thermal evolution of Europa's silicate interior, Europa, Pappalardo, R. T. et al. , eds., pp. 353368. Univ. of Arizona Press, TucsonGoogle Scholar
Selvans, Z. A., Wolf, A. S., & Pappalardo, R. T. 2010, A critical comparison of Europa's lineaments to non-synchronous rotation stresses, J. Geophys. Res.Google Scholar
Singer, K. N., McKinnon, W. B., & Schenk, P. M. 2010, Pits, spots, uplifts, and small chaos regions on Europa: Evidence for diapiric upwelling from morphology and morphometry, Lunar Planet. Sci. Conf. 41, Abstract #2195Google Scholar
Spohn, T. & Schubert, G. 2003, Oceans in the icy Galilean satellites of Jupiter?, Icarus, 161, 456467CrossRefGoogle Scholar
Squyres, S. W., Reynolds, R. T., Cassen, P., & Peale, S. J. 1983, Liquid water and active resurfacing of Europa, Nature, 301, 225226CrossRefGoogle Scholar
Stevenson, D. 2000, Europa's Ocean: The case strengthens, Science, 289, 13051307CrossRefGoogle ScholarPubMed
Sullivan, R. & 12 colleagues 1998, Episodic plate separation and fracture infill on the surface of Europa, Nature, 391, 371373CrossRefGoogle ScholarPubMed
Wahr, J., Selvans, Z. A., Mullen, M. E., Barr, A. C., Collins, G. C., Selvans, M. M., & Pappalardo, R. T. 2009, Modeling stresses on satellites due to nonsynchronous rotation and orbital eccentricity using gravitational potential theory, Icarus, 200, 188206CrossRefGoogle Scholar
Zimmer, C., Khurana, K. K., & Kivelson, M. G. 2000, Subsurface oceans on Europa and Callisto: Constraints from Galileo magnetometer observations, Icarus, 147, 329347CrossRefGoogle Scholar
Zahnle, K., Schenk, P., Levison, H. F., & Dones, L. 2003, Cratering rates in the outer solar system, Icarus, 163, 263289CrossRefGoogle Scholar
Zolotov, M. Yu & Kargel, J. S. 2009, On the chemical composition of Europa's icy shell, ocean, and underlying rocks, Europa, Pappalardo, R. T. et al. , eds., pp. 431458. Univ. of Arizona Press, TucsonGoogle Scholar