Key Results from Dawn’s Exploration of Vesta and Ceres

doi:10.1017/9781108856324.005

Part II - Key Results from Dawn’s Exploration of Vesta and Ceres

Published online by Cambridge University Press: 01 April 2022

Edited by

Simone Marchi ,

Carol A. Raymond and

Christopher T. Russell

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Simone Marchi: Affiliation:
Southwest Research Institute, Boulder, Colorado
Carol A. Raymond: Affiliation:
California Institute of Technology
Christopher T. Russell: Affiliation:
University of California, Los Angeles

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Type: Chapter
Information: Vesta and Ceres
Insights from the Dawn Mission for the Origin of the Solar System
, pp. 39 - 196

DOI: https://doi.org/10.1017/9781108856324.005 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2022

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References

Adams, J. B. (1974) Visible and near-infrared diffuse reflectance spectra of pyroxenes as applied to remote sensing of solid objects in the solar system. Journal of Geophysical Research, 79, 4829–4836.Google Scholar

Ammannito, E., De Sanctis, M. C., Capaccioni, F., et al. (2013a) Vestan lithologies mapped by the visual and infrared spectrometer on Dawn. Meteoritics & Planetary Science, 48, 2185–2198.Google Scholar

Ammannito, E., De Sanctis, M. C., Palomba, E., et al. (2013b) Olivine in an unexpected location on Vesta’s surface. Nature, 504, 122–125.CrossRef Google Scholar

Barrat, J.-A., & Yamaguchi, A. (2014) Comment on “The origin of eucrites, diogenites, and olivine diogenites: Magma ocean crystallization and shallow magma processes on Vesta” by B. E. Mandler and L. T. Elkins-Tanton. Meteoritics & Planetary Science, 49, 468–472.CrossRef Google Scholar

Barrat, J.-A., Yamaguchi, A., Bunch, T., et al. (2011) Possible fluid–rock interactions of differentiated asteroids recorded in eucritic meteorites. Geochimica et Cosmochimica Acta, 75, 3839–3852.CrossRef Google Scholar

Barrat, J.-A., Yamaguchi, A., Greenwood, R. C., et al. (2007) The Stannern trend eucrites: Contamination of main group eucritic magmas by crustal partial melts. Geochimica et Cosmochimica Acta, 71, 4108–4124.Google Scholar

Barrat, J.-A., Yamaguchi, A., Greenwood, R. C., et al. (2008) Geochemistry of diogenites: Still more diversity in their parental melts. Meteoritics & Planetary Science, 43, 1759–1775.Google Scholar

Bartels, K. S., & Grove, T. L. (1991) High-pressure experiments on magnesian eucrite compositions: Constraints on magmatic processes in the eucrite parent body. Proceedings of the Lunar & Planetary Science Conference, 21, 351–365.Google Scholar

Beck, A. W., Lawrence, D. J., Peplowski, P. N., et al. (2015) Using HED meteorites to interpret neutron and gamma-ray data from asteroid 4 Vesta. Meteoritics & Planetary Science, 50, 1311–1337.Google Scholar

Beck, A. W., Lawrence, D. J., Peplowski, P. N., et al. (2017) Igneous lithologies on asteroid (4) Vesta mapped using gamma-ray and neutron data. Icarus, 286, 35–45.CrossRef Google Scholar

Beck, A. W., McCoy, T. J., Sunshine, J. M., et al. (2013) Challenges in detecting olivine on the surface of 4 Vesta. Meteoritics & Planetary Science, 48, 2155–2165.CrossRef Google Scholar

Beck, A. W., & McSween, H. Y. (2010) Diogenites as polymict breccias composed of orthopyroxenite and harzburgite. Meteoritics & Planetary Science, 45, 850–872.Google Scholar

Beck, A. W., Mittlefehldt, D. W., McSween, H. Y., et al. (2011) MIL 03443, a dunite from asteroid 4 Vesta: Evidence for its classification and cumulate origin. Meteoritics & Planetary Science, 46, 1133–1151.CrossRef Google Scholar

Beck, A. W., Welten, K. C., McSween, H. Y., Viviano, C. E., & Caffee, M. W. (2012) Petrologic and textural diversity among the PCA 02 howardite group, one of the largest pieces of the Vestan surface. Meteoritics & Planetary Science, 47, 947–969.Google Scholar

Benedix, G. K., Haack, H., & McCoy, T. J. (2014) Iron and stony-iron meteorites. In Davis, A. M. (ed.), Treatise on Geochemistry, 2nd ed., Vol. 1. Oxford: Elsevier, pp. 267–285.Google Scholar

Binzel, R. P. (2012) A golden spike for planetary science. Science, 338, 203–204.Google Scholar

Binzel, R. P., Gaffey, M. J., Thomas, P., et al. (1997) Geologic mapping of Vesta from 1994 Hubble Space Telescope images. Icarus, 128, 95–103.CrossRef Google Scholar

Binzel, R. P., & Xu, S. (1993) Chips off of asteroid 4 Vesta: Evidence for the parent body of basaltic achondrite meteorites. Science, 260, 186–191.CrossRef Google Scholar PubMed

Bobrovnikoff, N. T. (1929) The spectra of minor planets. Lick Observatirt Bulletin, 14 (No. 407), 18–27.CrossRef Google Scholar

Bogard, D. D. (2011) K-Ar ages of meteorites: Clues to parent-body thermal histories. Chemie der Erde Geochemistry, 71, 207–226.Google Scholar

Bogard, D. D., & Garrison, D. H. (2010) ³⁹Ar-⁴⁰Ar ages of eucrites and the thermal history of asteroid 4 Vesta. Meteoritics & Planetary Science, 38, 669–710.Google Scholar

Buczkowski, D. L., Wyrick, D. Y., Toplis, M., et al. (2012) Large-scale troughs on Vesta: A signature of planetary tectonics. Geophysical Research Letters, 39, L18205.CrossRef Google Scholar

Cartwright, J. A., Ott, U., & Mittlefehldt, D. W. (2014) The quest for regolithic howardites. Part 2: Surface origins highlighted by noble gases. Geochimica et Cosmochimica Acta, 140, 488–508.Google Scholar

Cartwright, J. A., Ott, U., Mittlefehldt, D. W., et al. (2013) The quest for regolithic howardites. Part 1: Two trends uncovered using noble gases. Geochimica et Cosmochimica Acta, 105, 395–421.CrossRef Google Scholar

Clenet, H., Jutzi, M., Barrat, J.-A., et al. (2014) A deep crust–mantle boundary in the asteroid 4 Vesta. Nature, 511, 303–306.CrossRef Google Scholar PubMed

Cohen, B. (2013) The Vestan cataclysm: Impact-melt clasts in howardites and the bombardment history of 4 Vesta. Meteoritics & Planetary Science, 48, 771–785.Google Scholar

Combe, J.-P., McCord, T. B., McFadden, L. A., et al. (2015) Composition of the northern regions of Vesta analyzed by the Dawn mission. Icarus, 259, 53–71.Google Scholar

Consolmagno, J. G., & Drake, M. J. (1977) Composition and evolution of eucrite parent body – Evidence from rare earth elements. Geochimica et Cosmochimica Acta, 41, 1271–1282.Google Scholar

Consolmagno, J. G., Golabek, G. J., Turrini, D., et al. (2015) Is Vesta an intact and pristine protoplanet? Icarus, 254, 190–201.Google Scholar

Cruikshank, D. P., Tholen, D. J., Hartmann, W. K., Bell, J. F., & Brown, R. H. (1991) Three basaltic Earth-approaching asteroids and the source of basaltic meteorites. Icarus, 89, 1–13.Google Scholar

Cunningham, C. J. (2014) The First Four Asteroids: A History of Their Impact on English Astronomy in the Early Nineteenth Century. PhD thesis, University of Southern Queensland.Google Scholar

Day, J. M. D., Walker, R. J., Qin, L., & Rumble, D. (2012) Late accretion as a natural consequence of planetary growth. Nature Geoscience, 5, 614–617.Google Scholar

De Sanctis, M. C., Ammannito, E., Capria, M. T., et al. (2012a) Spectroscopic characterization of mineralogy and its diversity across Vesta. Science, 336, 697–700.Google Scholar

De Sanctis, M. C., Ammannito, E., Capria, M. T., et al. (2013) Vesta’s mineralogical composition as revealed by VIR on Dawn. Meteoritics & Planetary Science, 48, 2166–2184.Google Scholar

De Sanctis, M. C., Combe, J.-P., Ammannito, E., et al. (2012b) Detection of widespread hydrated materials on Vesta by the VIR imaging spectrometer on board the Dawn mission. Astrophysical Journal, 758, L36.Google Scholar

Denevi, B. W., Blewett, D. T., Buczkowski, D. L., et al. (2012) Pitted terrain on Vesta and implications for the presence of volatiles. Science, 338, 246–249.Google Scholar

Drake, M. J. (2001) The eucrite/Vesta story. Meteoritics & Planetary Science, 36, 501–513.CrossRef Google Scholar

Ermakov, A. I., Zuber, M. T., Smith, D. E., et al. (2014) Constraints on Vesta’s interior structure using gravity and shape models from the Dawn mission. Icarus, 240, 146–160.CrossRef Google Scholar

Formisano, M., Federico, C., Turrini, D., et al. (2013) The heating history of Vesta and the onset of differentiation. Meteoritics & Planetary Science, 48, 2316–2332.Google Scholar

Fu, R. R., Weiss, B. P., Shuster, D. L., et al. (2012) An ancient core dynamo in asteroid Vesta. Science, 338, 239–241.CrossRef Google Scholar PubMed

Gaffey, M. J. (1976) Spectral reflectance characteristics of the meteorite classes. Journal of Geophysical Research, 81, 905–920.Google Scholar

Gaffey, M. J. (1993) Forging an asteroid–meteorite link. Science, 260, 167–168.Google Scholar

Gaffey, M. J. (1997) Surface lithologic heterogeneity of asteroid 4 Vesta. Icarus, 127, 130–157.Google Scholar

Ghosh, A., & McSween, H. Y. (1998) A thermal model for the differentiation of asteroid 4 Vesta, based on radiogenic heating. Icarus, 134, 187–206.Google Scholar

Greenwood, R. C., Barrat, J.-A., Yamaguchi, A., et al. (2014) The oxygen isotope composition of diogenites: Evidence for early global melting on a single, compositionally diverse, HED parent body. Earth & Planetary Science Letters, 390, 165–174.Google Scholar

Gupta, G., & Sahijpal, S. (2010) Differentiation of Vesta and the parent bodies of other achondrites. Journal of Geophysical Research, 115, E08001.CrossRef Google Scholar

Haba, M. K., Wotzlaw, J.-W., Lai, Y.-J., et al. (2019) Mesosiderite formation on asteroid 4 Vesta by a hit-and-run collision. Nature Geoscience, 12, 510–515.Google Scholar

Hahn, T. M., Lunning, N. G., McSween, H. Y., et al. (2018) Mg-rich harzburgites from Vesta: Mantle residua or cumulates from planetary differentiation? Meteoritics & Planetary Science, 53, 514–546.CrossRef Google Scholar

Herzog, G. F. (2007) Cosmic-ray exposure ages of meteorites. In Holland, H. D., & Turekian, K. I. (eds.), Treatise on Geochemistry, Vol. 1. Oxford: Pergamon Press, pp. 711–746.Google Scholar

Jaumann, R. J., Williams, D. A., Buczkowski, D. L., et al. (2012) Vesta’s shape and morphology. Science, 336, 687–690.Google Scholar

Jutzi, M., Asphaug, E., Gillet, P., et al. (2013) The structure of asteroid 4 Vesta as revealed by models of planet-scale collisions. Nature, 494, 207–210.Google Scholar

Keil, K. (2002) Geological history of asteroid 4 Vesta: the “smallest terrestrial planet”. In Bottke, W., Cellino, A., Paolicchi, P., & Binzel, R. P. (eds.), Asteroids III. Tucson: University of Arizona Press, pp. 573–584.Google Scholar

Kleine, T., Touboul, M., Bourdon, B., et al. (2009) Hf-W chronology of the accretion and early evolution of asteroids and terrestrial planets. Geochimica et Cosmochimica Acta, 73, 5150–5188.Google Scholar

Konopliv, A. S., Asmar, S. W., Park, R. S., et al. (2014) The Vesta gravity field, spin pole and rotation period, landmark positions and ephemeris from the Dawn tracking and optical data. Icarus, 240, 103–117.CrossRef Google Scholar

Kruijer, T. S., Burkhardt, C., Budde, G., et al. (2017) Age of Jupiter inferred from the distinct genetics and formation times of meteorites. Proceedings of the National Academy of Sciences (USA), 114, 6712–6716.Google Scholar

Lazzaro, D., Michtchenco, T., Carvano, J. M., et al. (2000) Discovery of a basaltic asteroid in the outer Main Belt. Science, 288, 2033–2035.Google Scholar

Lorenz, K., Nazarov, M., Kurat, G., et al. (2007) Foreign meteoritic material of howardites and polymict eucrites. Petrology, 15, 109–125.CrossRef Google Scholar

Lunning, N. G., McSween, H. Y., Tenner, H. Y., et al. (2015) Olivine and pyroxene from the mantle of asteroid 4 Vesta. Earth & Planetary Science Letters, 418, 126–135.CrossRef Google Scholar

Lunning, N. G., Welten, K. C., McSween, H. Y., et al. (2016) Grosvenor Mountains 95 howardite pairing group: Insights into the surface regolith of asteroid 4 Vesta. Meteoritics & Planetary Science, 51, 167–194.Google Scholar

Mandler, B. E., & Elkins-Tanton, L. T. (2013) The origin of eucrites, diogenites, and olivine diogenites: Magma ocean crystallization and shallow magma chamber processes on Vesta. Meteoritics & Planetary Science, 48, 2333–2349.Google Scholar

Marchi, S., Bottke, W. F., Cohen, B. A., et al. (2013) High-velocity collisions from the lunar cataclysm recorded in asteroidal meteorites. Nature Geoscience, 6, 303–307.Google Scholar

Marchi, S., McSween, H. Y., O’Brien, D. P., et al. (2012) The violent collisional history of asteroid 4 Vesta. Science, 336, 690–694.CrossRef Google Scholar PubMed

Masiero, J. R., Mainzer, A. K., Bauer, J. M., et al. (2013) Asteroid family identification using the hierarchical clustering method and WISE/NEOWISE physical properties. Astrophysical Journal, 770, 7.Google Scholar

Mayne, R. G., McSween, H. Y., McCoy, T. J., et al. (2009) Petrology of the unbrecciated eucrites. Geochimica et Cosmochimica Acta, 73, 794–819.Google Scholar

McCord, T. B., Adams, J. B., & Johnson, T. V. (1970) Asteroid Vesta: Spectral reflectivity and compositional implications. Science, 168, 1445–1447.Google Scholar

McSween, H. Y., Ammannito, E., Reddy, V., et al. (2013a) Composition of the Rheasilvia basin, a window into Vesta’s interior. Journal of Geophysical Research, 118, 335–346.CrossRef Google Scholar

McSween, H. Y., Binzel, R. P., De Sanctis, M. C., et al. (2013b) Dawn; the Vesta-HED connection; and the geologic context for eucrites, diogenites, and howardites. Meteoritics & Planetary Science, 48, 2090–2014.Google Scholar

McSween, H. Y., Mittlefehldt, D. W., Beck, A. W., et al. (2011) HED meteorites and their relationship to the geology of Vesta and the Dawn mission. Space Science Reviews, 163, 141–174.Google Scholar

McSween, H. Y., Raymond, C. A., Stolper, E. M., et al. (2019) Differentiation and magmatic history of Vesta: Constraints from HED meteorites and Dawn spacecraft data. Geochemistry, 79, 125526.Google Scholar

Mittlefehldt, D. W. (1994) The genesis of diogenites and HED parent body petrogenesis. Geochimica et Cosmochimica Acta, 58, 1537–1552.CrossRef Google Scholar

Mittlefehldt, D. W. (2015) Asteroid (4) Vesta: I. The howardite-eucrite-diogenite (HED) clan of meteorites. Chemie der Erde Geochemistry, 75, 155–183.CrossRef Google Scholar

Mittlefehldt, D. W., Beck, A. W., Lee, C.-T. A., et al. (2012) Compositional constraints on the genesis of diogenites. Meteoritics & Planetary Science, 47, 72–98.Google Scholar

Mittlefehldt, D. W., Herrin, J. S., Quinn, J. E., et al. (2013) Composition and petrology of HED polymict breccias: the regolith of (4) Vesta. Meteoritics & Planetary Science, 48, 2105–2134.Google Scholar

Mittlefehldt, D. W., & Lindstrom, M. M. (2003) Geochemistry of eucrites: Genesis of basaltic eucrites, and Hf and Ta as petrogenetic indicators for altered Antarctic eucrites. Geochimica et Cosmochimica Acta, 67, 1911–1935.Google Scholar

Mittlefehldt, D. W., McCoy, T. J., Goodrich, C. A., et al. (1998) Non-chondritic meteorites from asteroidal bodies. In Papike, J. J. (ed.), Planetary Materials: Mineralogy & Petrology of Extraterrestrial Materials. Washington, DC: Mineralogical Society of America, pp. 4-1–4-195.Google Scholar

Neumann, W., Breuer, D., & Spohn, T. (2014) Differentiation of Vesta: Implications for a shallow magma ocean. Earth & Planetary Science Letters, 395, 267–280.CrossRef Google Scholar

Newsom, H. E., & Drake, M. J. (1982) The metal content of the eucrite parent body: Constraints from the partitioning behavior of tungsten. Geochimica et Cosmochimica Acta, 46, 2483–2489.CrossRef Google Scholar

O’Brien, D. P., Marchi, S., Morbidell, A., et al. (2015) Constraining the cratering chronology of Vesta. Planetary & Space Science, 103, 131–142.Google Scholar

Papike, J. J., Karner, J. M., & Shearer, C. K. (2003) Determination of planetary basalt parentage: A simple technique using the electron microprobe. American Mineralogist, 88, 469–472.CrossRef Google Scholar

Park, R. S., Konopliv, A. S., Asmar, S. W., et al. (2014) Gravity field expansion in ellipsoidal harmonic and polyhedral internal representations applied to Vesta. Icarus, 240, 118–132.Google Scholar

Prettyman, T. H., Mittlefehldt, D. W., Yamashita, N., et al. (2012) Elemental mapping by Dawn reveals exogenic H in Vesta’s regolith. Science, 338, 242–246.Google Scholar

Prettyman, T. H., Mittlefehldt, D. W., Yamashita, N., et al. (2013) Neutron absorption constraints on the composition of 4 Vesta. Meteoritics & Planetary Science, 48, 2211–2236.Google Scholar

Prettyman, T. H., Yamashita, N., Ammannito, E., et al. (2019) Elemental composition and mineralogy of Vesta and Ceres: Distribution and origins of hydrogen-bearing species. Icarus, 318, 42–55.CrossRef Google Scholar

Prettyman, T. H., Yamashita, N., Reedy, R. C., et al. (2015) Concentrations of potassium and thorium within Vesta’s regolith. Icarus, 259, 39–52.CrossRef Google Scholar

Raymond, C. A., Russell, C. T., & McSween, H. Y. (2017) Dawn at Vesta: Paradigms and paradoxes. In Elkins-Tanton, L., & Weiss, B. (eds.), Planetesimals. New York: Cambridge University Press, pp. 321–340.Google Scholar

Reddy, V., Le Corre, L., O’Brien, D. P., et al. (2012) Delivery of dark material to Vesta via carbonaceous chondritic impacts. Icarus, 221, 544–559.Google Scholar

Righter, K., & Drake, M. J. (1997) A magma ocean on Vesta: Core formation and petrogenesis of eucrites and diogenites. Meteoritics & Planetary Science, 32, 929–944.Google Scholar

Roig, F., & Nesvorny, D. (2020) Modeling the chronologies and size distributions of Ceres and Vesta. The Astronomical Journal, 160, 110.Google Scholar

Ruesch, O., Hiesinger, H., De Sanctis, M. C., et al. (2014) Detections and geologic context of local enrichments of olivine on Vesta with VIR/Dawn data. Journal of Geophysical Research, 119, 2078–2108.CrossRef Google Scholar

Russell, C. T., Raymond, C. A., Coradini, A., et al. (2012) Dawn at Vesta: Testing the protoplanetary paradigm. Science, 336, 684–686.Google Scholar

Ruzicka, A., Snyder, G. A., & Taylor, L. A. (1997) Vesta as the howardite, eucrite and diogenite parent body: Implications for the size of a core and for large-scale differentiation. Meteoritics & Planetary Science, 32, 825–840.Google Scholar

Sarafian, A. R., Roden, M. F., & Patino-Douce, A. E. (2013) The volatile content of Vesta: Clues from apatite in eucrites. Meteoritics & Planetary Science, 48, 2135–2154.Google Scholar

Schiller, M., Baker, J., Creech, J., et al. (2011) Rapid timescales for magma ocean crystallization on the howardite-eucrite-diogenite parent body. Astrophysical Journal Letters, 740, L22.Google Scholar

Schmedemann, N., Kneissl, T., Ivanov, B. A., et al. (2015) The cratering record, chronology and surface ages of (4) Vesta in comparison to smaller asteroids and ages of HED meteorites. Planetary & Space Science, 103, 104–130.Google Scholar

Scott, E. R. D., Greenwood, R. C., Franchi, I. A., & Sanders, I. S. (2009) Oxygen isotopic constraints on the origin and parent bodies of eucrites, diogenites, and howardites. Geochimica et Cosmochimica Acta, 73, 5835–5853.CrossRef Google Scholar

Scott, E. R. D., Krot, A. N., & Sanders, I. S. (2018) Isotopic dichotomy among meteorites and its bearing on the protoplanetary disk. Astrophysical Journal, 854, 164.CrossRef Google Scholar PubMed

Scully, J. E. C., Russell, C. T., Yin, A., et al. (2015) Geomorphological evidence for transient water flow on Vesta. Earth & Planetary Science Letters, 411, 151–163.Google Scholar

Shearer, C. K., Fowler, G. W., & Papike, J. J. (1997) Petrogenetic models for magmatism on the eucrite parent body: Evidence from orthopyroxene in diogenties. Meteoritics & Planetary Science, 32, 877–889.Google Scholar

Stolper, E. M. (1977) Experimental petrology of eucritic meteorites. Geochimica et Cosmochimica Acta, 41, 587–681.Google Scholar

Takeda, H., & Graham, A. L. (1991) Degree of equilibration of eucritic pyroxenes and thermal metamorphism of the earliest planetary crust. Meteoritics, 26, 129–134.Google Scholar

Thangjam, G., Reddy, V., Le Corre, L., et al. (2013) Lithologic mapping of HED terrains on Vesta using Dawn Framing Camera color data. Meteoritics & Planetary Science, 48, 2199–2210.Google Scholar

Thomas, P. C., Binzel, R. P., Gaffey, M. J., et al. (1997) Impact excavation on asteroid 4 Vesta: Hubble Space Telescope results. Science, 277, 1492–1495.Google Scholar

Toplis, M. J., Mizzon, H., Monnereau, M., et al. (2013) Chondritic models of 4 Vesta: Implications for geochemical and geophysical properties. Meteoritics & Planetary Science, 48, 2300–2315.Google Scholar

Treiman, A. H. (1997) The parent magmas of cumulate eucrites: A mass balance approach. Meteoritics & Planetary Science, 32, 138–146.Google Scholar

Trinquier, A., Birck, J. L., Allegre, C. J., et al. (2008) ⁵³Mn–⁵³Cr systematics of the early solar system revisited. Geochimica et Cosmochimica Acta, 72, 5146–5163.Google Scholar

Unsulan, O., Jenniskens, P., Yin, Q.-Z., et al. (2019) The Saricicek howardite fall in Turkey: Source crater of HED meteorites on Vesta and impact risk of vestoids. Meteoritics & Planetary Science, 54, 953–1008.Google Scholar

Warren, P. H., Kallemeyn, G. W., Huber, H., et al. (2009) Siderophile and other geochemical constraints on mixing relationships among HED-meteoritic breccias. Geochimica et Cosmochimica Acta, 73, 5918–5943.Google Scholar

Wasson, J. T. (2013) Vesta and extensively melted asteroids: Why HED meteorites are probably not from Vesta. Earth & Planetary Science Letters, 381, 138–146.CrossRef Google Scholar

Welten, K. C., Lindner, L., Van Der Borg, K., et al. (1997) Cosmic-ray exposure ages of diogenites and the recent collisional history of the howardite, eucrite and diogenite parent body/bodies. Meteoritics & Planetary Science, 32, 891–902.Google Scholar

Wetherill, G. W. (1987) Dynamical relations between asteroids, meteorites and Apollo-Amor objects. Philosophical Transactions of the Royal Society of London, Series A, 323, 323–336.Google Scholar

Williams, D. A., Jaumann, R., McSween, H. Y., et al. (2014) The chronostratigraphy of protoplanet Vesta. Icarus, 244, 158–165.Google Scholar

Wilson, L., & Keil, K. (2012) Volcanic activity on differentiated asteroids: A review and analysis. Chemie der Erde, 72, 289–321.Google Scholar

Wisdom, J. (1985) Meteorites may follow a chaotic route to Earth. Nature, 315, 731–733.CrossRef Google Scholar

Zellner, B., Storrs, A. W., Wells, E., et al. (1997). Hubble Space Telescope images of asteroid 4 Vesta. Icarus, 128, 83–87.Google Scholar

Zellner, B., Tholen, D. J., & Tedesco, E. F. (1985) The eight-color asteroid survey: Results for 589 minor planets. Icarus, 61, 355–416.Google Scholar

Zolensky, M. E., Weisberg, M. K., Buchanan, P. C., et al. (1996) Mineralogy of carbonaceous chondrite clasts in HED meteorites. Meteoritics & Planetary Science, 31, 518–537.Google Scholar

References

Ammannito, E., De Sanctis, M. C., Palomba, E., et al. (2013) Olivine in an unexpected location on Vesta’s surface. Nature, 504, 122–125.Google Scholar

Arzi, A. A. (1978) Critical phenomena in the rheology of partially melted rocks. Tectonophysics, 44, 173–184.CrossRef Google Scholar

Bagdassarov, N., Golabek, G. J., Solferino, G., & Schmidt, M. W. (2009) Constraints on the Fe-S melt connectivity in mantle silicates from electrical impedance measurements. Physics of the Earth and Planetary Interiors, 177, 139–146.Google Scholar

Barrat, J.-A., Yamaguchi, A., Greenwood, R. C., et al. (2008) Geochemistry of diogenites: Still more diversity in their parental melts. Meteoritics & Planetary Science, 43, 1759–1775.Google Scholar

Barrat, J.-A., Yamaguchi, A., Zanda, B., Bollinger, C. & Bohn, M. (2010) Relative chronology of crust formation on asteroid 4-Vesta: Insights from the geochemistry of diogenites. Geochimica et Cosmochimica Acta, 74, 6218–6231.Google Scholar

Best, M. G. (2002) Igneous and Metamorphic Petrology, 2nd ed. Hoboken, NJ: Wiley-Blackwell.Google Scholar

Bizzarro, M., Baker, J. A., & Haack, H. (2004) Mg isotope evidence for contemporaneous formation of chondrules and refractory inclusions. Nature, 431, 275–278.Google Scholar

Boyet, M., Carlson, R. W., & Horan, M. (2010) Old Sm–Nd ages for cumulate eucrites and redetermination of the Solar System initial ¹⁴⁶Sm/¹⁴⁴Sm ratio. Earth and Planetary Science Letters, 291, 172–181.Google Scholar

Brearley, A. J., & Jones, R. H. (1998) Chondritic meteorites. In Papike, J. J. (ed.), Planetary Materials. Reviews in Mineralogy, Vol. 36. Washington, DC: Mineralogical Society of America, pp. 3–39.Google Scholar

Britt, D. T., & Consolmagno, S. J. (2003) Stony meteorite porosities and densities: A review of the data through 2001. Meteoritics & Planetary Science, 38, 1161–1180.Google Scholar

Buczkowski, D. L., Wyrick, D. Y., Toplis, M. J., et al. (2014) The unique geomorphology and physical properties of the Vestalia Terra plateau. Icarus, 244, 89–103.Google Scholar

Cameron, A. G. W. (1993) Nucleosynthesis and star formation. In Levy, E. H., & Lunine, J. I. (eds.), Protostars and Planets III. Tucson: University of Arizona Press, p. 47.Google Scholar

Castillo-Rogez, J., Johnson, T. V., Lee, M. H., et al. (2009) ²⁶Al decay: Heat production and a revised age for Iapetus. Icarus, 204, 658–662.Google Scholar

Consolmagno, G. J., Golabek, G. J., Turrini, D., et al. (2015). Is Vesta an intact and pristine protoplanet? Icarus, 254, 190–201.Google Scholar

Dodson, M. H. (1973) Closure temperature in cooling geochronological and petrological systems. Contributions to Mineralogy and Petrology, 40, 259–274.Google Scholar

Drake, M. J. (2001) The eucrite/Vesta story. Meteoritics & Planetary Science, 36, 501–513.Google Scholar

Ermakov, A. I., Zuber, M. T., Smith, D. E., et al. (2014) Constraints on Vesta’s interior structure using gravity and shape models from the Dawn mission. Icarus, 240, 146–160.Google Scholar

Formisano, M., Federico, C., DeAngelis, S., DeSantis, M. C., & Magni, G. (2016) A core dynamo in Vesta? Monthly Notices of the Royal Astronomical Society, 458, 695–707.Google Scholar

Formisano, M., Federico, C., Turrini, D., et al. (2013) The heating history of Vesta and the differentiation of Vesta. Meteoritics & Planetary Science, 48, 2316–2332.Google Scholar

Fu, R. R., Hager, B. H., Ermakov, A. I., & Zuber, M. T. (2014) Efficient early global relaxation of asteroid Vesta. Icarus, 240, 133–145.Google Scholar

Fu, R. R., Weiss, B. P., Schuster, D. L., et al. (2012) An ancient core dynamo in asteroid Vesta. Science, 338, 238–241.Google Scholar

Ganguly, J., Ito, M., & Zhang, X. (2007) Cr diffusion in orthopyroxene: Experimental determination, ⁵³Mn–⁵³Cr thermochronology, and planetary applications. Geochimica et Cosmochimica Acta, 71, 3915–3925.Google Scholar

Ghosh, A., & McSween, H. Y. Jr. (1988) A thermal model for the differentiation of asteroid 4 Vesta, based on radiogenic heating. Icarus, 134, 187–206.Google Scholar

Gupta, G., & Sahijpal, S. (2010) Differentiation of Vesta and the parent bodies of other achondrites. Journal of Geophysical Research, 115, E08001.Google Scholar

Güttler, C., Krause, M., Geretshauser, R., Speith, R., & Blum, J. (2009) The physics of protoplanetesimal dust agglomerates. IV. Towards a dynamical collision model. The Astrophysical Journal, 701, 130–141.Google Scholar

Henke, S., Gail, H.-P., Trieloff, M., Schwarz, W. H., & Kleine, T. (2012) Thermal history modelling of the h chondrite parent body. Astronomy and Astrophysics, 545, A135.Google Scholar

Hevey, P. J., & Sanders, I. S. (2006) A model for planetesimal meltdown by ²⁶Al and its implications for meteorite parent bodies. Meteoritics & Planetary Science, 41, 95–106.Google Scholar

Hublet, G., Debaille, V., Wimpenny, J., & Yin, Q. (2017) Differentiation and magmatic activity in Vesta evidenced by ²⁶Al-²⁶Mg dating in eucrites and diogenites. Geochimica et Cosmochimica Acta 218, 73–97.Google Scholar

Iizuka, T., Jourdan, F., Yamaguchi, A., et al. (2019) The geologic history of Vesta inferred from combined ²⁰⁷Pb/²⁰⁶Pb and ⁴⁰Ar/³⁹Ar chronology of basaltic eucrites. Geochimica et Cosmochimica Acta, 267, 275–299.Google Scholar

Iizuka, T., Yamaguchi, A., Haba, M. K., et al. (2015) Timing of global crustal metamorphism on Vesta as revealed by high-precision U-Pb dating and trace element chemistry. Earth and Planetary Science Letters, 409, 182–192.Google Scholar

Jones, J. H. (1984) The composition of the mantle of the eucrite parent body and the origin of eucrites. Geochimica et Cosmochimica Acta, 48, 641–648.Google Scholar

Jourdan, F., Kennedy, T., Benedix, G. K., Eroglu, E., & Mayer, C. (2020) Timing of the magmatic activity and upper crustal cooling of differentiated asteroid 4 Vesta. Geochimica et Cosmochimica Acta, 273, 205–225.Google Scholar

Jutzi, M., Asphaug, E., Gillet, P., Barrat, J. A., & Benz, W. (2013) The structure of the asteroid 4 Vesta as revealed by models of planet-scale collisions. Nature, 494, 207–210.Google Scholar

Kennedy, A. K., Lofgren, G. E., & Wasserburg, G. J. (1993) An experimental study of trace element partitioning between olivine, orthopyroxene, and melt in chondrules: equilibrium values and kinetic effects. Earth and Planetary Science Letters, 115, 177–195.Google Scholar

Kleine, T., Mezger, K., Münker, C., Palme, H., & Bischoff, A. (2004) ¹⁸²Hf–¹⁸²W isotope systematics of chondrites, eucrites, and martian meteorites: Chronology of core formation and early mantle differentiation in Vesta and Mars. Geochimica et Cosmochimica Acta, 68, 2935–2946.Google Scholar

Laporte, D., & Provost, A. (2000) The grain-scale distribution of silicate, carbonate and metallosulfide partial melts: A review of theory and experiments. In Bagdassarov, N., Laporte, D., & Thompson, A. B. (eds.), Physics and Chemistry of Partially Molten Rocks. Dordrecht: Springer, pp. 93–140.Google Scholar

Lee, T., Papanastassiou, D. A., & Wasserburg, G. J. (1976) Demonstration of ²⁵Mg excess in Allende and evidence for ²⁶Al. Geophysical Research Letters, 3, 41–44.Google Scholar

Lejeune, A.-M., & Richet, P. (1995) Rheology of crystal bearing silicate melts: An experiment study at high viscosities. Journal of Geophysical Research, 100, 4215–4229.Google Scholar

Lichtenberg, T., Keller, T., Katz, R. F., Golabek, G. J., & Gerya, T. V. (2019) Magma ascent in planetesimals: Control by grain size. Earth and Planetary Science Letters, 507, 154–165.Google Scholar

Lugmair, G. W., & Shukolyukov, A. (1998) Early Solar System timescales according to ⁵³Mn-⁵³Cr systematics. Geochimica et Cosmochimica Acta, 62, 2863–2886.Google Scholar

MacPherson, G. J., Davis, A. M., & Zinner, E. K. (1995) The distribution of aluminium-26 in the early Solar System – A reappraisal. Meteoritics, 30, 365–386.Google Scholar

Marchi, S., Bottke, W. F., Cohen, B. A., et al. (2013) High-velocity collisions from the lunar cataclysm recorded in asteroidal meteorites. Nature Geoscience, 6, 303–307.Google Scholar

Marsh, C. A., Della-Giustina, D. N., Giacalone, J., & Lauretta, D. S. (2006) Experimental tests of the induction heating hypothesis for planetesimals. 37th Annual Lunar and Planetary Science Conference, March 13–17, Houston, TX, 2078 (abstract).Google Scholar

McCoy, T. J., Keil, K., Muenow, D. W., & Wilson, L. (1997) Partial melting and melt migration in the acapulcoite-lodranite parent body. Geochimica and Cosmochimica Acta, 61, 639–650.Google Scholar

McSween, H. Y., Ammannito, E., Reddy, V., et al. (2013) Composition of the Rheasilvia basin, a window into Vesta’s interior. Journal of Geophysical Research: Planets, 118, 335–346.Google Scholar

McSween, H. Y., Mittlefehldt, D. W., Beck, A. W., Mayne, R. G., & McCoy, T. J. (2010) HED meteorites and their relationship to the geology of Vesta and the Dawn mission. Space Science Reviews, 163, 141–174.Google Scholar

Mittlefehldt, D. W. (1994) The genesis of diogenites and HED parent body petrogenesis. Geochimica et Cosmochimica Acta, 58, 1537–1552.Google Scholar

Mizzon, H. (2015) The Magmatic Crust of Vesta. PhD thesis, Universite Toulouse III Paul Sabatier.Google Scholar

Montmerle, T., Augereau, J.-C., Chaussidon, M., et al. (2006) From suns to life: A chronological approach to the history of life on Earth 3. Solar System formation and early evolution: The first 100 million years. Earth Moon and Planets, 98, 39–95.Google Scholar

Morse, S. A. (1980) Basalts and Phase Diagrams: An Introduction to the Quantitative Use of Phase Diagrams in Igneous Petrology. New York: Springer-Verlag.Google Scholar

Moskovitz, N., & Gaidos, E. (2011) Differentiation of planetesimals and the thermal consequences of melt migration. Meteoritics & Planetary Science, 46, 903–918.Google Scholar

Moskovitz, N. A. (2009) Spectroscopic and Theoretical Constraints on the Differentiation of Planetesimals. PhD thesis, University of Hawaii.Google Scholar

Mostefaoui, S., Lugmair, G. W., & Hoppe, P. (2005) ⁶⁰Fe: A heat source for planetary differentiation from a nearby supernova explosion. The Astrophysical Journal, 625, 271–277.Google Scholar

Neri, A., Guignard, J., Monnereau, M., Toplis, M. J., & Quitté, G. (2019) Melt segregation in planetesimals: Constraints from experimentally constrained interfacial energies. Earth and Planetary Science Letters, 518, 40–52.Google Scholar

Neumann, W., Breuer, D., & Spohn, T. (2012) Differentiation and core formation in accreting planetesimals. Astronomy & Astrophysics, 543, 1–21.Google Scholar

Neumann, W., Breuer, D., & Spohn, T. (2014) Differentiation of Vesta: Implications for a shallow magma ocean. Earth and Planetary Science Letters, 395, 267–280.Google Scholar

Nyquist, L. E., Takeda, H., Bansal, B. M., et al. (1986) Rb-Sr and Sm-Nd internal isochron ages of a subophitic basalt clast and matrix sample from the Y75011 eucrite. Journal of Geophysical Research, 91, 8137–8150.Google Scholar

Ogliore, R. C., Huss, G. R., & Nagashima, K. (2011) Ratio estimation in SIMS analysis. Nuclear Instruments and Methods, Physics Research B: Beam Interactions with Materials and Atoms, 269, 19101918.CrossRef Google Scholar

Pack, A., & Palme, H. (2003) Partitioning of Ca and Al between forsterite and silicate melt in dynamic systems with implications for the origin of Ca, Al-rich forsterites in primitive meteorites. Meteoritics & Planetary Science, 38, 1263–1281.Google Scholar

Park, R. S., Konopliv, A. S., Asmar, S. W., Bills, B. G., & Gaskell, R. W. (2014) Gravity field expansion in ellipsoidal harmonic and polyhedral internal representations applied to Vesta. Icarus, 240, 118–132.CrossRef Google Scholar

Quitté, G., Markowski, A., Latkoczy, C., Gabriel, A., & Pack, A. (2010) Iron-60 heterogeneity and incomplete isotope mixing in the early Solar System. The Astrophysical Journal, 720, 1215–1224.Google Scholar

Rao, A. S., & Chaklader, A. C. D. (1972) Plastic flow during hot-pressing. Journal of the American Ceramic Society, 55, 596–601.Google Scholar

Raymond, C. A., Russell, C. T., & McSween, H. Y. (2016) Dawn at Vesta: Paradigms and paradoxes. In Elkins-Tanton, L., & Weiss, B. (eds.), Planetesimals. Cambridge: Cambridge University Press, pp. 321–340.Google Scholar

Righter, K., & Drake, M. J. (1997). A magma ocean on Vesta: Core formation and petrogenesis of eucrites and diogenites. Meteoritics & Planetary Science, 32, 929–944.Google Scholar

Russell, C. T., & Raymond, C. A. (2012) The Dawn mission to Vesta and Ceres. Space Science Reviews, 163, 3–23.Google Scholar

Russell, C. T., Raymond, C. A., Coradini, A., et al. (2012) Dawn at Vesta: Testing the protoplanetary paradigm. Science, 336, 684–686.Google Scholar

Ruzicka, A., Snyder, G. A., & Taylor, L. A. (1997) Vesta as the howardite, eucrite, and diogenite parent body: Implications for the size of a core and for large-scale differentiation. Meteoritics & Planetary Science, 32, 825–840.Google Scholar

Sahijpal, S., Soni, P., & Gupta, G. (2007) Numerical simulations of the differentiation of accreting planetesimals with ²⁶Al and ⁶⁰Fe as the heat sources. Meteoritics & Planetary Science, 42, 1529–1548.Google Scholar

Schiller, M., Baker, J., Creech, J., et al. (2011). Rapid timescales for magma ocean crystallization on the Howardites–Eucrite–Diogenite parent body. The Astrophysical Journal, 740, L22.Google Scholar

Scott, T., & Kohlstedt, D. L. (2006) The effect of large melt fraction on the deformation behavior of peridotite. Earth and Planetary Science Letters, 246, 177–187.Google Scholar

Shearer, C. K., Fowler, G. W., & Papike, J. J. (1997) Petrogenetic models for magmatism on the eucrite parent body: Evidence from orthopyroxene in diogenites. Meteoritics & Planetary Science, 32, 877–889.Google Scholar

Shukolyukov, A., & Lugmair, G. W. (1993) Fe-60 in eucrites. Earth and Planetary Science Letters, 119, 159–166.Google Scholar

Smoliar, M. I. (1993) A survey of Rb-Sr systematics of eucrites. Meteoritics, 28, 105–113.Google Scholar

Sonnett, C. P., Colburn, D. S., & Schwartz, K. (1968) Electrical heating of meteorite parent bodies and planets by dynamo induction from a premain sequence t tauri solar wind. Nature, 219, 924–926.Google Scholar

Šrámek, O., Milelli, L., Ricard, Y., & Labrosse, S. (2012) Thermal evolution and differentiation of planetesimals and planetary embryos. Icarus, 217, 339–354.Google Scholar

Srinivasan, G., Goswami, J. N., & Bhandari, N. (1999) Al-26 in eucrite Piplia Kalan: Plausible heat source and formation chronology. Science, 284, 1348–1350.Google Scholar

Stolper, E. M. (1975) Petrogenesis of eucrite, howardite and diogenite meteorites. Nature, 258, 220–222.Google Scholar

Tachibana, S., & Huss, G. R. (2003) The initial abundance of ⁶⁰Fe in the Solar System. The Astrophysical Journal Letters, 588, L41–L44.Google Scholar

Takahashi, E. (1983) Melting of a Yamato L3 chondrite (Y-74191) up to 30 kbar. National Institute of Polar Research, Memoirs, Special Issue (ISSN 0386-0744), no. 30.Google Scholar

Takahashi, K., & Masudat, A. (1990) Young ages of two diogenites and their genetic implications. Nature, 343, 540–542.Google Scholar

Taylor, G. J. (1992) Core formation in asteroids. Journal of Geophysical Research, 97, 14717–14726.Google Scholar

Taylor, G. J., Keil, K., McCoy, T. J., Haack, H., & Scott, E. R. D. (1993) Asteroid differentiation: Pyroclastic volcanism to magma oceans. Meteoritics, 28, 34–52.Google Scholar

Telus, M., Huss, G. R., Ogliore, R. C., Nagashima, K., & Tachibana, S. (2012) Recalculation of data for short-lived radionuclide systems using less-biased ratio estimation. Meteoritics & Planetary Science, 47, 2013–2030.Google Scholar

Terasaki, H., Frost, D. J., Rubie, D. C., & Langenhorst, F. (2008) Percolative core formation in planetesimals. Earth and Planetary Science Letters, 273, 132–137.Google Scholar

Touboul, M., Sprung, P., Aciego, S. M., Bourdon, B., & Kleine, T. (2015) Hf–W chronology of the eucrite parent body. Geochimica et Cosmochimica Acta, 156, 106–121.Google Scholar

Trinquier, A., Birck, J. L., Allegre, C. J., Göpel, C., & Ulfbeck, D. (2008) (53)Mn-(53)Cr systematics of the early Solar System revisited. Geochimica et Cosmochimica Acta, 72, 5146–5163.Google Scholar

Turcotte, D. L., & Phipps Morgan, J. (1992) The physics of magma migration and mantle flow beneath a mid-ocean ridge. Mantle flow and melt migration beneath oceanic ridges: Models derived from observations in ophiolites. In: Phipps Morgan, J., Blackman, D. K., & Sinton, J. M. (eds.), Mantle Flow and Melt Generation at Mid-Ocean Ridges, vol. 71, Geophysical Monograph. Washington, DC: American Geophysical Union, pp. 155–182.Google Scholar

Urey, H. C. (1955) The cosmic abundances of potassium, uranium, and thorium and the heat balance of the earth, the moon, and mars. Proceedings of the National Academy of Sciences (USA), 41, 127–144.Google Scholar

Villeneuve, J., Chaussidon, M., & Libourel, G. (2009) Homogeneous distribution of ²⁶Al in the Solar System from the Mg isotopic composition of chondrules. Science, 325, 985–988.Google Scholar

von Bargen, N., & Waff, H. S. (1986) Permeabilities, interfacial areas and curvatures of partially molten systems: results of numerical computations of equilibrium microstructures. Journal of Geophysical Research, 91, 9261–9276.CrossRef Google Scholar

Waff, H. S., & Bulau, J. R. (1979) Equilibrium fluid distribution in an ultramafic partial melt under hydrostatic stress conditions. Journal of Geophysical Research, 84, 6109–6114.Google Scholar

Walker, D., & Agee, C. B. (1988) Ureilite compaction. Meteoritics, 23, 81–91.Google Scholar

Wark, D. A., Williams, C. A., Watson, E. B., & Price, J. D. (2003). Reassessment of pore shapes in microstructurally equilibrated rocks, with implications for permeability of the upper mantle. Journal of Geophysical Research, 108, 2050.Google Scholar

Wasson, J. T., & Kallemeyn, G. W. (1990) Compositions of chondrites. Philosophical Transactions of the Royal Society of London, 325, 535–544.Google Scholar

Wiggins, C., & Spiegelman, M. (1995) Magma migration and magmatic solitary waves in 3D. Geophysical Research Letter, 22, 1289–1292.Google Scholar

Wilson, L., & Keil, K. (2012) Volcanic activity on differentiated asteroids: A review and analysis. Chemie der Erde – Geochemistry, 72, 289–321.Google Scholar

Yamaguchi, A., Barrat, J.-A., Greenwood, R. C., et al. (2009) Crustal partial melting on Vesta: Evidence from highly metamorphosed eucrites. Geochimica et Cosmochimica Acta, 73, 7162–7182.Google Scholar

Yamaguchi, A., Taylor, G. J., & Keil, K. (1996) Global crustal metamorphism of the eucrite parent body. Icarus, 124, 97–112.Google Scholar

Yomogida, K., & Matsui, T. (1984) Multiple parent bodies of ordinary chondrites. Earth and Planetary Science Letters, 68, 34–42.Google Scholar

Zhou, Q., Yin, Q.-Z., Young, E. D., et al. (2013) SIMS Pb–Pb and U-Pb age determination of eucrite zircons at < 5 µm scale and the first 50 Ma of the thermal history of Vesta. Geochimica et Cosmochimica Acta, 110, 152–175.Google Scholar

References

Asphaug, E., Moore, J. M., Morrison, D., et al. (1996) Mechanical and geological effects of impact cratering on Ida. Icarus, 120, 158–184.Google Scholar

Barrat, J. A., Yamaguchi, A., Zanda, B., Bollinger, C., & Bohn, M. (2010) Relative chronology of crust formation on asteroid Vesta: Insights form the geochemistry of diogenites. Geochimica et Cosmochimica Acta, 74, 6218–6231.Google Scholar

Beck, A. W., & McSween, H. Y. (2010) Diogenites as polymict breccias composed of orthopyroxenite and harzburgite. Meteoritics & Planetary Science, 45, 850–872.Google Scholar

Binzel, R. P., Gaffey, M. J., Thomas, B. H., et al. (1997) Geologic mapping of Vesta from 1994 Hubble Space Telescope images, Icarus, 128, 95–103.Google Scholar

Binzel, R. P., & Xu, S. (1993) Chips off of asteroid 4 Vesta: Evidence for the parent body of basaltic achondrite meteorites. Science, 260, 186–191.Google Scholar

Bogard, D. D. (1995) Impact ages of meteorites: A synthesis. Meteoritics, 30, 244.Google Scholar

Bogard, D. D. (2011) K–Ar ages of meteorites: Clues to parent-body thermal histories. Chemie der Erde – Geochemistry, 71, 207–226.Google Scholar

Bogard, D. D., & Garrison, D. H. (2003) ³⁹Ar–⁴⁰Ar ages of eucrites and thermal history of asteroid 4Vesta. Meteoritics and Planetary Science, 38, 669–710.Google Scholar

Bowling, T. J., Johnson, B. C., & Melosh, H. J. (2013a) Formation of equatorial graben following the Rheasilvia impact on asteroid 4 Vesta. 44th Lunar & Planetary Science Conference, March 18–22, Houston, TX, abs. 1673.Google Scholar

Bowling, T. J., Johnson, B. C., Melosh, H. J., et al. (2013b) Antipodal terrains created by the Rheasilvia basin forming impact on asteroid 4 Vesta. Journal of Geophysical Research, 118, 1821–1834.Google Scholar

Boyce, J. M., Wilson, L., Mouginis-Mark, P. J., Hamilton, C. W., & Tornabene, L. L. (2012) Origin of small pits in martian impact craters. Icarus, 221, 262.Google Scholar

Buczkowski, D. L., Barnouin, O. S., & Prockter, L. M. (2008) 433 Eros lineaments: Global mapping and analysis. Icarus, 193, 39–52.Google Scholar

Buczkowski, D. L., Schmidt, B., Williams, D. A., et al. (2016) The geomorphology of Ceres. Science, 353, aaf4332.CrossRef Google Scholar PubMed

Buczkowski, D. L., Wyrick, D. Y., Iyer, K. A., et al. (2012) Large-scale troughs on Vesta: A signature of planetary tectonics. Geophysical Research Letters, 39, L18205.Google Scholar

Buczkowski, D. L., Wyrick, D. Y., Toplis, M., et al. (2014) The unique geomorphology and physical properties of the Vestalia Terra plateau. Icarus, 244, 89–103.Google Scholar

Carsenty, U., Wagner, R. J., Buczkowski, D. L., et al. (2013) The “swarm” – A peculiar crater chain on Vesta. 44th Lunar & Planetary Science Conference, March 18–22, Houston, TX, abs. 1492.Google Scholar

Cohen, B. A. (2013) The Vestan cataclysm: Impact-melt clasts in howardites and the bombardment history of 4 Vesta. Meteoritics & Planetary Science, 48, 771–785.Google Scholar

Consolmagno, G. J., & Drake, M. J. (1977) Composition of the eucrite parent body: Evidence from rare Earth elements. Geochimica et Cosmochimica Acta, 41, 1271–1282.Google Scholar

De Sanctis, M. C., Ammannito, E., Buczkowski, D., et al. (2014) Compositional evidence of magmatic activity on Vesta. Geophysical Research Letters, 41, 3038–3044.Google Scholar

De Sanctis, M. C., Ammannito, E., Capria, M. T., et al. (2012a) Spectroscopic characterization of mineralogy and its diversity across Vesta. Science, 336, 697–700.Google Scholar

De Sanctis, M. C, Combe, J.–Ph., Ammannito, E., et al. (2012b) Detection of widespread hydrated materials on Vesta by the VIR imaging spectrometer on board the Dawn mission. Astrophysical Journal Letters, 758, L36.Google Scholar

De Sanctis, M. C., Coradini, A., Ammannito, E., et al. (2011) The VIR spectrometer. Space Science Reviews, 163, 329–369.Google Scholar

Denevi, B. W., Blewett, D. T., Buczkowski, D. L., et al. (2012) Pitted terrain on Vesta and implications for the presence of volatiles. Science, 338, 246–249.Google Scholar

Drake, M. J. (1979) Geochemical evolution of the eucrite parent body: Possible evolution of Asteroid 4 Vesta? In Gehrels, T., & Matthews, M. S. (eds.), Asteroids. Tucson: University of Arizona Press, pp. 765–782.Google Scholar

Drake, M. J. (2001) Presidential address: The eucrite/Vesta story. Meteoritics & Planetary Science, 36, 501–513.Google Scholar

Ferrill, D. A., & Morris, A. P. (2003) Dilational normal faults. Journal of Structural Geology, 25, 183–196.Google Scholar

Ferrill, D. A., Wyrick, D. Y., Morris, A. P., Sims, D. W., & Franklin, N. M. (2004) Dilational fault slip and pit chain formation on Mars, GSA Today, 14, 4–12.Google Scholar

Ferrill, D. A., Wyrick, D. Y., & Smart, K. J. (2011) Coseismic, dilational‐fault and extension‐fracture related pit chain formation in Iceland: Analog for pit chains on Mars. Lithosphere, 3, 133–142.Google Scholar

Gaffey, M. J. (1997) Surface lithologic heterogeneity of asteroid 4 Vesta. Icarus, 127, 130–157.Google Scholar

Garry, W. B., Williams, D. A., Yingst, R. A., et al. (2014) Geologic mapping of ejecta deposits in Oppia Quadrangle, Asteroid (4) Vesta. Icarus, 244, 104–119.Google Scholar

Hartmann, W. K., Quantin, C., Werner, S. C., & Popova, O. (2010) Do young Martian ray craters have ages consistent with the crater count system? Icarus, 208, 621.Google Scholar

Hasegawa, S., Murakawa, K., Ishiguro, M., et al. (2003) Evidence of hydrated and/or hydroxylated minerals on the surface of asteroid 4 Vesta. Geophysical Research Letters, 30, 2123.Google Scholar

Horstman, K. C., & Melosh, H. J. (1989) Drainage pits in cohesionless materials – Implications for the surface of PHOBOS. Journal of Geophysical Research, 94, 12433–12441.Google Scholar

Ivanov, B. A., & Melosh, H. J. (2013) Two-dimensional numerical modeling of the Rheasilvia impact formation. Journal of Geophysical Research, 118, 1545–1557. doi:10.1002/jgre.20108Google Scholar

Jaumann, R., Nass, A., Otto, K., et al. (2014) The geological nature of dark material on Vesta and implications for the subsurface structure. Icarus, 240, 3–19.Google Scholar

Jaumann, R., Williams, D. A., Buczkowski, D. L., et al. (2012) Vesta’s shape and morphology. Science, 336, 687–690.Google Scholar

Jutzi, M., & Asphaug, E. (2011) Mega‐ejecta on asteroid Vesta. Geophysical Research Letters, 38, L01102.Google Scholar

Keil, K. (2002) Geologial history of asteroid 4 Vesta: The “smallest terrestrial planet”. In Bottke, W. F., Cellino, A., Paolicchi, P., & Binzel, R. P. (eds.), Asteroids III. Tucson: University of Arizona Press, pp. 573–584.CrossRef Google Scholar

Keil, K., Stoffler, D., Love, S. G., & Scott, E. R. D. (1997) Constraints on the role of impact heating and melting in asteroids. Meteoritics and Planetary Science, 32, 349–363.Google Scholar

Keil, K., & Wilson, L. (2012) Volcanic eruption and intrusion processes on 4 Vesta: A reappraisal. 43rd Lunar Planetary Science Conference, Abs. 1127, Houston, TX: Lunar Planetary Institute.Google Scholar

Krohn, K., Jaumann, R., Elbeshausen, D., et al. (2014a) Bimodal craters: Impacts on slopes. Planetary and Space Science, 103, 36–56.Google Scholar

Krohn, K., Jaumann, R., Otto, K., et al. (2014b) Mass movement on Vesta at steep scarps and crater rims. Icarus, 244, 120–132.Google Scholar

Liu, Z., Yue, Z., Michael, G., et al. (2018) A global database and statistical analyses of (4) Vesta craters. Icarus, 311, 242–257.Google Scholar

Marchi, S., Bottke, W. F., Cohen, B. A., et al. (2013a) High-velocity collisions from the lunar cataclysm recorded in asteroidal meteorites. Nature Geoscience, 6, 411.Google Scholar

Marchi, S., Bottke, W. F., O’Brien, D. P., et al. (2013b) Small crater populations on Vesta. Planetary and Space Science, 103, 96–103.Google Scholar

Marchi, S., McSween, H. Y., O’Brien, D. P., et al. (2012) The violent collisional history of Asteroid 4 Vesta. Science, 336, 690.Google Scholar

Martin, E. S., & Kattenhorn, S. A. (2013) Probing regolith depths on Enceladus by exploring a pit chain proxy. Lunar and Planetary Science Conference XLIV, #2047.Google Scholar

Martin, E. S., Kattenhorn, S. A., Collins, G. C., et al. (2017) Pit chains on Enceladus signal the recent tectonic dissection of the ancient cratered terrains. Icarus, 294, 209–217.Google Scholar

McCord, T. B., Adams, J. B., & Johnson, T. V. (1970) Asteroid Vesta: Spectral reflectivity and compositional implications. Science, 168, 1445–1447.Google Scholar

McCord, T. B., Li, J.-Y., Combe, J.-P., et al. (2012) Dark material on Vesta from the infall of carbonaceous volatile-rich material. Nature, 491, 83–86.Google Scholar

McEwen, A. S., Hansen, C. J., Delamere, W. A., et al. (2007) A closer look at water-related geologic activity on Mars. Science, 317, 1706.Google Scholar

McSween, H. Y. J., Binzel, R. P., De Sanctis, M. C., et al. (2013) Dawn; the Vesta–HED connection; and the geologic context for eucrites, diogenites, and howardites. Meteoritics & Planetary Science, 48, 2090–2104.Google Scholar

McSween, H. Y. J., Mittledfehldt, D. W., Beck, A. W., Mayne, R. G., & McCoy, T. J. (2011) HED meteorites and their relationship to the geology of Vesta and the Dawn mission, Space Science Review, 163, 141–174.Google Scholar

McSween, H. Y. J., Raymond, C. A., Stolper, E. M., et al. (2019) Differentiation and magmatic history of Vesta: Constraints from HED meteorites and Dawn spacecraft data. Geochemistry, 79, 125526.Google Scholar

Michaud, R. L., Pappalardo, R. T., & Collins, G. C. (2008) Pit chains on Enceladus: A discussion of their origin. Lunar and Planetary Science, XXXIX, abs. #1678.Google Scholar

Mittlefehldt, D. W., McCoy, T. J., Goodrich, C. A., & Kracher, A. (1998) Non-chondritic meteorites from asteroidal bodies. In Papike, J. J. (ed.), Planetary Materials. Washington, DC: Mineralogical Society of America, pp. 4-1–4-195.Google Scholar

Mouginis-Mark, P. J., & Garbeil, H. (2007) Crater geometry and ejecta thickness of the Martian impact crater Tooting. Meteoritics & Planetary Science, 42, 1615–1625.Google Scholar

O’Brien, D. P., Marchi, S., Morbidelli, A., et al. (2014) Constraining the cratering chronology of Vesta. Planetary and Space Science, 103, 131–142.Google Scholar

Okubo, C. H., & Martel, S. J. (1998) Pit crater formation on Kilauea volcano, Hawaii. Journal of Volcanology and Geothermal Research, 86, 1–18.Google Scholar

Otto, K. A., Jaumann, R., Krohn, K., et al. (2013) Mass-wasting features and processes in Vesta’s south polar basin Rheasilvia. Journal of Geophysical Research, 118, 2279–2294.Google Scholar

Prettyman, T. H., Feldman, W. C., McSween, H. Y. Jr., et al. (2011) Dawn’s gamma ray and neutron detector. Space Science Reviews, 163, 371–459.Google Scholar

Prettyman, T. H., Mittlefehldt, D. W., Yamashita, N., et al. (2012) Elemental mapping by Dawn reveals exogenic H in Vesta’s regolith. Science, 338, 242–246.Google Scholar

Preusker, F., Scholten, F., Matz, K.-D., et al. (2012) Topography of Vesta from Dawn FC stereo images. 43rd Lunar Planetary Science Conference, Abs. 2012. Houston, TX: Lunar and Planetary Institute.Google Scholar

Preusker, F., Scholten, F., Matz, K.-D., et al. (2014) Global shape of Vesta from Dawn FC stereo images. 45th Lunar Planetary Science Conference, abs. 2027. Houston, TX: Lunar and Planetary Institute.Google Scholar

Prockter, L., Thomas, P., Robinson, M., et al. (2002) Surface expressions of structural features on Eros. Icarus, 155, 75–93.Google Scholar

Raymond, C. A., Park, R. S., Asmar, S. W., et al. (2013) Vestalia Terra: An ancient mascon in the southern hemisphere of Vesta. 44^th Lunar Planetary Science Conference, Abs. 2882. Houston, TX: Lunar and Planetary Institute.Google Scholar

Raymond, C. A., Russell, C. T., & McSween, H. Y. (2017) Dawn at Vesta: Paradigms and paradoxes. In Elkins-Tanton, L., & Weiss, B. (eds.), Planetesimals: Early Differentiation and Consequences for Planets. Cambridge: Cambridge University Press, pp. 321–340.Google Scholar

Reddy, V., Le Corre, L., O’Brien, D. P., et al. (2012a) Delivery of dark material to Vesta via carbonaceous chondritic impacts. Icarus, 221, 544–559.Google Scholar

Reddy, V., Nathues, A., Le Corre, L., et al. (2012b) Color and albedo heterogeneity of Vesta from Dawn. Science, 336, 700–704.Google Scholar

Russell, C. T., Raymond, C. A., Coradini, A., et al. (2012) Dawn at Vesta: Testing the protoplanetary paradigm. Science, 336, 684–686.Google Scholar

Schaefer, M., Natheus, A., Williams, D. A., et al. (2014) Imprint of the Rheasilvia impact on Vesta – Geologic mapping of quadrangles Gegania and Lucaria. Icarus, 244, 60–73.Google Scholar

Schenk, P., O’Brien, D., Marchi, S., et al. (2012) The geologically recent giant impact basins at Vesta’s south pole. Science, 336, 694.Google Scholar

Schiller, M., Baker, J. A., Bizzaro, M., Creech, J., & Irving, A. J. (2010) Timing and mechanisms of the evolution of the magma ocean on the HED parent body. 73rd Annual Meteorical Society Meeting, Abst. 5042. New York: Lunar Planetary Institute.Google Scholar

Schmedemann, N., Kneissl, T., Ivanov, B., et al. (2014) The cratering record, chronology and surface ages of (4) Vesta in comparison to smaller asteroids and the ages of the HED meteorites. Planetary and Space Science, 103, 104–130.Google Scholar

Scully, J. E. C., Buczkowski, D. L., Schmedemann, N., et al. (2017) Evidence for the interior evolution of Ceres from geologic analysis of fractures. Geophysical Research Letters, 44, 9564–9572.Google Scholar

Scully, J. E. C., Russell, C. T., Yin, A., et al. (2015) Geomorphical evidence for transient water flow on Vesta. Earth and Planetary Science Letters, 411, 151–163.Google Scholar

Sierks, H., Keller, H. U., Jaumann, R., et al. (2011) The Dawn Framing Camera. Space Science Reviews, 163, 263–327.Google Scholar

Stephan, K., Jaumann, R., De Sanctis, M. C., et al. (2014) A compositional and geological view of fresh ejecta of small impact craters on Asteroid 4 Vesta. Journal of Geophysical Research, 119, 2013JE004388.Google Scholar

Stickle, A. M., Schultz, P. H., & Crawford, D. A. (2015) Subsurface failure in spherical bodies: A formation scenario for linear troughs on Vesta’s surface. Icarus, 247, 18–34.Google Scholar

Sullivan, R., Greeley, R., Pappalardo, R., et al. (1996) Geology of 243 Ida. Icarus, 120, 119–139.Google Scholar

Takeda, H. (1979) A layered-crust model of a howardite parent body. Icarus, 40, 455–470.Google Scholar

Takeda, H. (1997) Mineralogical records of early planetary processes on the howardite, eucrite, diogenite parent body with reference to Vesta. Meteoritic and Planetary Science, 32, 841–853.Google Scholar

Thomas, N., Barbieri, C., Keller, H. U., et al. (2012) The geomorphology of (21) Lutetia: Results from the OSIRIS imaging system onboard ESA’s Rosetta spacecraft. Planetary and Space Science, 66, 96–124.Google Scholar

Thomas, P. (1979) Surface features of Phobos and Deimos. Icarus, 40, 223–243.Google Scholar

Thomas, P. C., Binzel, R. P., Gaffey, M. J., et al. (1997) Impact excavation on asteroid 4 Vesta: Hubble Space Telescope results. Science, 277, 1492–1495.Google Scholar

Tornabene, L. L., Osinski, G. R., McEwen, A. S., et al. (2012) Widespread crater-related pitted materials on Mars: Further evidence for the role of target volatiles during the impact process. Icarus, 220, 348.Google Scholar

Trombka, J. I., Squyres, S. W., Bruckner, J., et al. (2000) The elemental composition of asteroid 433 Eros: Results of the NEAR-Shoemaker X-ray spectrometer. Science, 289, 2101–2105.Google Scholar

Veverka, J., Thomas, P., Simonelli, D., et al. (1994) Discovery of grooves on Gaspra. Icarus, 107, 399–411.Google Scholar

Whitten, J. L., & Martin, E. S. (2019) Icelandic pit chains as planetary analogs: Using morphologic measurements of pit chains to determine regolith thickness. Journal of Geophysical Research, 124, 2983–99.Google Scholar

Williams, D. A., Denevi, B. W., Mittlefehldt, D. W., et al. (2014a) The geology of the Marcia quadrangle of asteroid Vesta: Assessing the effects of large, young craters. Icarus, 244, 74–88.Google Scholar

Williams, D. A., O’Brien, D. P., Schenk, P. M., et al. (2013) Lobate and flow-like features on asteroid Vesta, Planetary and Space Science, 103, 24–35.Google Scholar

Williams, D. A., Yingst, R. A., & Garry, B. (2014b) Introduction: The geologic mapping of Vesta. Icarus, 244, 1–12.Google Scholar

Wilson, L., Bland, P., Buczkowski, D., Keil, K., & Krot, S. (2015) Hydrothermal and magmatic fluid flow in asteroids. In Michel, P., DeMeo, F., & Bottke, W. (eds.), Asteroids IV. Tucson: University of Arizona Press, pp. 553–572.Google Scholar

Wilson, L., & Keil, K. (1996) Volcanic eruptions and intrusions on the asteroid 4 Vesta. Journal of Geophysical Research, 101, 18927.Google Scholar

Wyrick, D., Ferrill, D. A., Morris, A. P., Colton, S. L., & Sims, D. W. (2004) Distribution, morphology and origins of Martian pit crater chains. Journal of Geophysical Research, 109, E06005.Google Scholar

Wyrick, D. Y., Buczkowski, D. L., Bleamaster, L. F., & Collins, G. C. (2010) Pit crater chains across the Solar System. 41st Lunar Planetary Science Conference, Abs. 1413. Houston, TX: Lunar and Planetary Institute.Google Scholar

Zellner, B. H., Albrecht, R., Binzel, R. P., et al. (1997) Hubble Space Telescope images of Asteroid 4 Vesta in 1994. Icarus, 128, 83–87.Google Scholar

Zellner, N. E. B., Gibbard, S., de Pater, I., Marchis, F., & Gaffey, M. J. (2005) Near-IR imaging of asteroid 4 Vesta. Icarus, 177, 190–195.Google Scholar

References

Adams, J. B. (1974) Visible and near-infrared diffuse reflectance spectra of pyroxenes as applied to remote sensing of solid objects in the Solar System. Journal of Geophysical Research 79, 4829– 4836.Google Scholar

Adams, J. B. (1975) Interpretation of visible and near-infrared diffuse reflectance spectra of pyroxenes and other rock-forming minerals. In Karr, C. Jr. (ed.), Infrared and Raman Spectroscopy of Lunar and Terrestrial Minerals. New York: Academic Press, Inc., pp. 91–116.Google Scholar

Adams, J. B., & Goullaud, L. H. (1978) Plagioclase feldspars: Visible and near infrared diffuse reflectance spectra as applied to remote sensing. Proceedings of the 9th Lunar and Planetary Science Conference, March 13–17, Houston, TX, pp. 2901–2909.Google Scholar

Ammannito, E., De Sanctis, M. C., Combe, J.-P, et al. (2015) Compositional variations in the Vestan Rheasilvia basin. Icarus, 259, 194–202.Google Scholar

Ammannito, E., De Sanctis, M. C., Palomba, E., et al. (2013) Olivine in an unexpected location on Vesta’s surface. Nature 504, 122–125.Google Scholar

Batista, S. F. A., Seixas, T. M., Salgueiro da Silva, M. A., & de Albuquerque, R. M. G. (2014) Mineralogy of V-type asteroids as a constraining tool of their past history. Planetary and Space Science 104, 295–309.Google Scholar

Beck, A. W., Lawrence, D. J., Peplowski, P. N., et al. (2015) Using HED meteorites to interpret neutron and gamma-ray data from asteroid 4 Vesta. Meteoritics & Planetary Science 50, 1311–1337.Google Scholar

Beck, A. W., Lawrence, D. J., Peplowski, P. N., et al. (2017) Igneous lithologies on asteroid (4) Vesta mapped using gamma-ray and neutron data. Icarus 286, 35–45.Google Scholar

Beck, A. W., McCoy, T. J., Sunshine, J. M., et al. (2013) Challenges in detecting olivine on the surface of 4 Vesta. Meteoritics & Planetary Science 48, 2155–2165.Google Scholar

Beck, A. W., & McSween, H. Y. (2010) Diogenites as polymict breccias composed of or- thopyroxenite and harzburgite. Meteoritics & Planetary Science 45, 850–872.Google Scholar

Bell, P. M., & Mao, H. K. (1973) Optical and chemical analysis of iron in Luna 20 plagioclase. Geochimica et Cosmochimica Acta 37, 755–758.Google Scholar

Blewett, D. T., Denevi, B. W., Le Corre, L., et al. (2016) Optical space weathering on Vesta: Radiative transfer models and Dawn observations. Icarus 265, 161–174Google Scholar

Bradley, J. P., Keller, L. P., Brownlee, D. E., & Thomas, L. (1996) Reflectance spectroscopy of interplanetary dust particles. Meteoritics & Planetary Science 31, 394–402.Google Scholar

Brunetto, R., Loeffler, M. J., Nesvorný, D., et al. (2015) Asteroid surface alteration by space weathering processes. In Michel, P., DeMeo, F. E., & Bottke, W. F. (eds.), Asteroids IV. Tucson: University of Arizona Press, pp. 597–616.Google Scholar

Buchanan, P. C., & Mittlefehldt, D. W. (2003) Lithic components in the paired howardites EET 87503 and EET 87513: Characterization of the regolith of 4 Vesta. Antartic Meteorite Research 16, 128–151.Google Scholar

Buchanan, P. C., Zolensky, M. E., & Reid, A. M. (1993) Carbonaceous chondrite clasts in the howardites Bholghati and EET87513. Meteoritics 28, 659–669.Google Scholar

Burbine, T. H., Buchanan, P. C., Dolkar, T., & Binzel, R. P. (2009) Pyroxene mineralogies of near-Earth vestoids. Meteoritics & Planetary Science 44, 1331–1341.Google Scholar

Burbine, T. H., DeMeo, F. E., Rivkin, A. S., & Reddy, V. (2017) Evidence for differentiation among asteroid families. In Elkins-Tanton, L. T., & Weiss, B. P. (eds.), Planetesimals: Early Differentiation and Consequences for Planets. Cambridge: Cambridge University Press, pp. 298–320.Google Scholar

Burns, R. G. (1970) Crystal field spectra and evidence of cation ordering in olivine minerals. American Mineralogist 55, 1608–1632.Google Scholar

Burns, R. G. (1993) Mineralogical Applications of Crystal Field Theory. Cambridge: Cambridge University Press.Google Scholar

Busarev, V. V. (2011) Asteroids 10 Hygiea, 135 Hertha, and 196 Philomela: Heterogeneity of the material from the reflectance spectra. Solar System Research 45, 43–52.Google Scholar

Cahill, J. T. S., Blewett, D. T., Nguyen, N. V., et al. (2012) Determination of iron metal optical constants: Implications for ultraviolet, visible, and near-infrared remote sensing of airless bodies. Geophysical Research Letters 39, L10204.Google Scholar

Carrozzo, F. G., Raponi, A., Sanctis, M. C., et al. (2016) Artefacts removal in VIR/DAWN data. Review of Scientific Instruments 87, 124501.Google Scholar

Chapman, C. R., & Salisbury, J. W. (1973) Comparisons of meteorite and asteroid spectral reflectivities. Icarus 19, 507–552.Google Scholar

Cheek, L. C., & Pieters, C. M. (2014) Reflectance spectroscopy of plagioclase-dominated mineral mixtures: Implications for characterizing lunar anorthosites remotely. American Mineralogist 99, 1871–1892.Google Scholar

Clark, R. N. (1983) Spectral properties of mixtures of montmorillonite and dark grains – Implications for remote sensing minerals containing chemically and physically adsorbed water. Journal of Geophysical Research 88, 10635–10644.Google Scholar

Clark, R. N., Swayze, G. A., Gallagher, A., King, T. V. V., & Calvin, W. M. (1993) The US Geological Survey, Digital Spectral Library: Version 1: 0.2 to 3.0 µm, US Geological Survey, Open File Report 93-5922.Google Scholar

Clenet, H., Jutzi, M., Barrat, J.-A., et al. (2014) A deep crust-mantle boundary in the asteroid 4 Vesta. Nature 511, 303–306.Google Scholar

Cloutis, E. A., & Gaffey, M. J. (1991) Pyroxene spectroscopy revisited – Spectral–compositional correlations and relationship to geothermometry. Journal of Geophysical Research 96, 22,809–22,826.Google Scholar

Cloutis, E. A., Izawa, M. R. M., Pompilio, L., et al. (2013) Spectral reflectance properties of HED meteorites + CM2 carbonaceous chondrites: Comparison to HED grain size and compositional variations and implications for the nature of low-albedo features on Asteroid 4 Vesta. Icarus 223, 850–877.Google Scholar

Combe, J.-Ph. (in preparation) Calcium-poor pyroxenes and plagioclase on the northern regions of Vesta: An alternative interpretation to olivine. Planetary Science Journal.Google Scholar

Combe, J.-Ph., Ammannito, E., Tosi, F., et al. (2015a) Reflectance properties and hydrated material distribution on Vesta: Global investigation of variations and their relationship using improved calibration of Dawn VIR mapping spectrometer. Icarus 259, 21–38.Google Scholar

Combe, J.-Ph., Le Mouélic, S., Launeau, P., Irving, A. J., & McCord, T. B. (2011) Imaging spectrometry of meteorite samples relevant to Vesta and the Moon. 42nd Lunar and Planetary Science Conference, March 7–11, The Woodlands, Texas. LPI Contribution No. 1608, p. 2449.Google Scholar

Combe, J.-Ph., Le Mouélic, S., Sotin, C., et al. (2008) Analysis of OMEGA/Mars Express data hyperspectral data using a Multiple-Endmember Linear Spectral Unmixing Model (MELSUM): Methodology and first results. Planetary and Space Science 56, 951–975.Google Scholar

Combe, J.-Ph., McCord, T. B., McFadden, L. A., et al. (2015b) Composition of the northern regions of Vesta analyzed by the Dawn mission. Icarus 259, 53–71.Google Scholar

Conel, J. E., & Nash, D. B. (1970) Spectral reflectance and albedo of Apollo 11 lunar samples: Effects of irradiation and vitrification and comparison with telescopic observations. Proceedings of the Apollo 11 Lunar Science Conference 3, 2013–2024.Google Scholar

Consolmagno, G. J. (1979) REE patterns versus the origin of the basaltic achondrites. Asteroids and Icarus 40, 522–530.Google Scholar

Consolmagno, G. J., & Drake, M. J. (1977) Composition and evolution of the eucrite parent body: Evidence from rare earth elements. Geochimica et Cosmochimica Acta 41, 1271–1282.Google Scholar

Dalton, J. B., & Pitman, K. M. (2012) Low temperature optical constants of some hydrated sulfates relevant to planetary surfaces. Journal of Geophysical Research 117.Google Scholar

Daly, R. T., & Schultz, P. H. (2016) Delivering a projectile component to the vestan regolith. Icarus 264, 9–19.Google Scholar

Day, J. M. D., Walker, R. J., Qing, L., et al. (2012) Late accretion as a natural consequence of planetary growth. Nature Geoscience 9, 614–617.Google Scholar

De Sanctis, M.-C., Ammannito, E., Capria, M.-T., et al. (2013) Vesta’s mineralogical composition as revealed by the visible and infrared spectrometer on Dawn. Meteoritics & Planetary Science 48, 2166–2184.Google Scholar

De Sanctis, M. C., Combe, J.-P., Ammannito, E., et al. (2012) Detection of widespread hydrated materials on Vesta by the VIR imaging spectrometer on board the Dawn mission. The Astrophysical Journal Letters 758, L36.Google Scholar

De Sanctis, M. C., Coradini, A., Ammannito, E., et al. (2011) The VIR spectrometer. Space Science Reviews 163, 329–369.Google Scholar

Denevi, B. W., Blewett, D. T., Buczkowski, D. L., et al. (2012) Pitted terrain on Vesta and implications for the presence of volatiles. Science 338, 246.Google Scholar

Drake, M. J. (2001) The eucrite/Vesta story. Meteoritics & Planetary Science 36, 501–513.CrossRef Google Scholar

Feierberg, M. H., Larson, H., Fink, U., & Smith, H. (1980) Spectroscopic evidence for at least two achondritic parent bodies. Geochimica et Cosmochimica Acta 44, 513–521.Google Scholar

Feierberg, M. H., Lebofsky, L. A., & Tholen, D. J. (1985) The nature of C-class asteroids from 3-μm spectrophotometry. Icarus 63, 183–191.Google Scholar

Fornasier, S., Lantz, C., Barucci, M. A., & Lazzarin, M. (2014) Aqueous alteration on Main Belt primitive asteroids: Results from visible spectroscopy. Icarus 233, 163–178.Google Scholar

Fornasier, S., Mottola, S., Barucci, M. A., et al. (2011) Photometric observations of asteroid 4 Vesta by the OSIRIS cameras onboard the Rosetta spacecraft. Astronomy & Astrophysics 533, 131–146.Google Scholar

Gaffey, M. J. (1976) Spectral reflectance characteristics of the meteorite classes. Journal of Geophysical Research 81, 905–920.Google Scholar

Gaffey, M. J. (1997) Surface lithologic heterogeneity of Asteroid 4 Vesta Icarus 127, 130–157.Google Scholar

Gaffey, M. J. (2010) Space weathering and the interpretation of asteroid reflectance spectra. Icarus 209, 564–574.Google Scholar

Gaffey, M. J., Reddy, V., Fieber-Beyer, S., & Cloutis, E. A. (2015) Asteroid (354) Eleonora: Plucking an odd duck. Icarus 250, 623–638.Google Scholar

Gounelle, M. J., Zolensky, M. E., Liou, J.-C., Bland, P. A., & Alard, O. (2003) Mineralogy of carbonaceous chondritic microclasts in howardites: Identification of C2 fossil micrometeorites. Geochimica et Cosmochimica Acta 67, 507–527.Google Scholar

Greenwood, R. C., Franchi, I. A., Jambon, A., Barrat, J. A., & Burbine, T. H. (2006) Oxygen isotope variation in stony-iron meteorites. Science 313, 1763–1765.Google Scholar

Hapke, B. (1981) Bidirectional reflectance spectroscopy: 1. Theory. Journal of Geophysical Research 86, 3039–3054.Google Scholar

Hasegawa, S., Hiroi, T., Ishiguro, M., et al. (2004) Spectroscopic observations of asteroid 4 Vesta from 1.9 to 3.5 microns: Evidence of hydrated and/or hydroxylated minerals. 35th Lunar and Planetary Science Conference, March 15–19, League City, TX, abstract# 1458.Google Scholar

Hasegawa, S., Murakawa, K., Ishiguro, M., et al. (2003) Evidence of hydrated and/or hydroxylated minerals on the surface of asteroid 4 Vesta. Geophysical Research Letters 30, 2123.Google Scholar

Hazen, R. M., Bell, P. M., & Mao, H. K. (1978) Effects of compositional variation on absorption spectra of lunar pyroxenes. Proceedings of the 9th Lunar and Planetary Science Conference, March 13–17, Houston, TX, 3. (A79–39253 16-91) New York, Pergamon Press, Inc., pp. 2919–2934.Google Scholar

Hiroi, T., Abe, M., Kitazato, K., et al. (2006) Developing space weathering on the asteroid 25143 Itokawa. Nature 443, 56–58.Google Scholar

Hunt, G. R. (1977) Spectral signatures of particulate minerals in the visible and near infrared. Geophysics 42, 501–513.Google Scholar

Ikeda, Y., & Takeda, H. (1985) A model for the origin of basaltic achondrites based on the Yamato 7308 howardite. Journal of Geophysical Research 90, C649–C663.Google Scholar

Jaumann, R., Nass, A., Otto, K., et al. (2014) The geological nature of dark material on Vesta and implications for the subsurface structure. Icarus 240, 3–19.Google Scholar

Jutzi, M., Asphaug, E., Gillet, P., Barrat, J.-A., & Benz, W. (2013) The structure of the asteroid 4 Vesta as revealed by models of planet-scale collisions. Nature 494, 207–210.Google Scholar

Klima, R. L., Dyar, M. D., & Pieters, C. M. (2011) Near‐infrared spectra of clinopyroxenes: Effects of calcium content and crystal structure. Meteoritics & Planetary Science 46, 379–395.Google Scholar

Klima, R. L., Pieters, C. M., & Dyar, M. D. (2007) Spectroscopy of synthetic Mg‐Fe pyroxenes I: Spin‐allowed and spin‐forbidden crystal field bands in the visible and near‐infrared. Meteoritics & Planetary Science 42, 235–253.Google Scholar

Klima, R. L., Pieters, C. M., & Dyar, M. D. (2008) Characterization of the 1.2 μm M1 pyroxene band: Extracting cooling history from near‐IR spectra of pyroxenes and pyroxene‐dominated rocks. Meteoritics & Planetary Science 43, 1591–1604.Google Scholar

Lantz, C., Binzel, R. P., & DeMeo, F. E. (2018) Space weathering trends on carbonaceous asteroids: A possible explanation for Bennu’s blue slope? Icarus 302, 10–17.Google Scholar

Lapôtre, M. G. A., Ehlmann, B. L., & Minson, S. E. (2017) A probabilistic approach to remote compositional analysis of planetary surfaces. Journal of Geophysical Research Planets 122, 983–1009.Google Scholar

Larson, H. P. (1977) Asteroid surface compositions from infrared spectroscopic observations: Results and prospects. In Delsemme, A. H. (ed.), Comet, Asteroids, MeteoritesToledo, OH: University of Toledo Press, pp. 219–228.Google Scholar

Lawrence, D. J., Peplowski, P. N., Prettyman, T. H., et al. (2013) Constraints on Vesta’s elemental composition: Fast neutron measurements by Dawn’s gamma ray and neutron detector. Meteoritics & Planetary Science 48, 2271–2288.Google Scholar

Le Corre, L., Reddy, V., Sanchez, J. A., et al. (2015) Exploring exogenic sources for the olivine on Asteroid (4) Vesta. Icarus 258, 483–499.Google Scholar

Le Corre, L., Reddy, V., Schmedemann, N., et al. (2013) Olivine or impact melt: Nature of the “Orange” material on Vesta from Dawn. Icarus 226, 1568–1594.Google Scholar

Lebofsky, L. A. (1980) Infrared reflectance spectra of asteroids: A search for water of hydration. Astronomical Journal 85, 573–585.Google Scholar

Li, J.-Y., Mittlefehldt, D. W., Pieters, C. M., et al. (2012) Investigating the origin of bright materials on Vesta: Synthesis, conclusions, and implications. Lunar and Planetary Science Conference, 43, Abstract #2381.Google Scholar

Loeffler, M. J., Baragiola, R. A., & Murayama, M. (2008) Laboratory simulations of redeposition of impact ejecta on mineral surfaces. Icarus 196, 285–292.Google Scholar

Loeffler, M. J., Dukes, C. A., & Baragiola, R. A. (2009) Irradiation of olivine by 4 keV He⁺: Simulation of space weathering by the solar wind. Journal of Geophysics Research 114, E03003.Google Scholar

Mann, A. (2018) Bashing holes in the tale of Earth’s troubled youth. Nature 553, 393–395.Google Scholar

Marchi, S., Bottke, W. F., Cohen, B., et al. (2013) High-velocity collisions from the lunar cataclysm recorded in asteroidal meteorites. Nature Geoscience 6, 303–307.Google Scholar

Marchi, S., Raponi, A., Prettyman, T. H., et al. (2019) An aqueously altered carbon-rich Ceres. Nature Astronomy 3, 140–145.Google Scholar

Matsuoka, M., Nakamura, T., Hiroi, T., et al. (2020) Space weathering simulation with low-energy laser irradiation of Murchison CM chondrite for reproducing micrometeoroid bombardments on C-type asteroids. The Astrophysical Journal Letters 890, 1–12.Google Scholar

Mayne, R. G., McSweenJr., H. Y., McCoy, T. J., & Gale, A. (2009) Petrology of the unbrecciated eucrites, Geochimica et Cosmochimica Acta 73, 794–819.Google Scholar

McCord, T. B., Adams, J. B., & Johnson, T. V. (1970) Asteroid Vesta: Spectral reflectivity and compositional implications. Science 168, 1445–1447.Google Scholar

McCord, T. B., Li, J.-Y., Combe, J.-P., et al. (2012) Dark material on Vesta from the infall of carbonaceous volatile-rich material. Nature 491, 83–86.Google Scholar

McCord, T. B., & Scully, J. E. C. (2015) The composition of Vesta from the Dawn mission. Icarus 259, 1–9.Google Scholar

McFadden, L. A., McCord, T. B., & Pieters, C. M. (1977) Vesta: The first pyroxene band from new spectroscopic measurements. Icarus 31, 439–446.Google Scholar

McSween, H. Y., Ammannito, E., Reddy, V., et al. (2013) Composition of the Rheasilvia basin, a window into Vesta’s interior. Journal of Geophysical Research: Planets 118, 335–346.Google Scholar

Mittlefehldt, D. W. (1994) The genesis of diogenites and HED parent body petrogenesis. Geochimica et Cosmochimica Acta 58, 1537–1552.Google Scholar

Mittlefehldt, D. W. (2015) Asteroid (4) Vesta: I. The howardite–eucrite–diogenite (HED) clan of meteorites. Chemie der Erde 75, 155–183.Google Scholar

Mittlefehldt, D. W., & Lindstrom, M. M. (1993) Geochemistry and petrology of a suite of ten Yamato HED meteorites. Seventeenth Symposium on Antarctic Meteorites. Proceedings of the NIPR Symposium, No. 6, August 19–21, 1992, National Institute of Polar Research, Tokyo, 268.Google Scholar

Murchie, S., Robinson, M., Clark, B. E., et al. (2002) Color variations on Eros from NEAR multispectral imaging. Icarus 155, 145–168.Google Scholar

Nakamura, T., Noguchi, T., Tanaka, M., et al. (2011) Itokawa dust particles: A direct link between S-type asteroids and ordinary chondrites. Science 333, 1113.Google Scholar

Nathues, A., Hoffmann, M., Cloutis, E. A., et al. (2014) Detection of serpentine in exogenic carbonaceous chondrite material on Vesta from Dawn FC data. Icarus 239, 222–237.Google Scholar

Nathues, A., Hoffmann, M., Schäfer, M., et al. (2015) Exogenic olivine on Vesta from Dawn Framing Camera color data. Icarus 258, 467–482.Google Scholar

Noble, S. K., Keller, L. P., & Pieters, C. M. (2011) Evidence of space weathering in regolith breccias II: Asteroidal regolith breccias. Meteoritics & Planetary Science 45, 2007–2015.Google Scholar

Noble, S. K., Pieters, C. M., & Keller, L. P. (2005) Evidence of space weathering in regolith breccias I: Lunar regolith breccias. Meteoritics & Planetary Science 40, 397–408.Google Scholar

Noble, S. K., Pieters, C. M., & Keller, L. P. (2007) An experimental approach to understanding the optical effects of space weathering. Icarus 192, 629–642.Google Scholar

Noble, S. K., Pieters, C. M., Taylor, L. A., et al. (2001) The optical properties of the finest fraction of lunar soil: Implications for space weathering. Meteoritics & Planetary Science 36, 31–42.Google Scholar

Noguchi, T., Nakamura, T., Kimura, M., et al. (2011) Incipient space weathering observed on the surface of Itokawa dust particles. Science 333, 1121.Google Scholar

O’Brien, D. P., & Sykes, M. V. (2011) The origin and evolution of the asteroid belt – Implications for Vesta and Ceres. Space Science Reviews 163, 41–61.Google Scholar

Palomba, E., Combe, J. P., McCord, T. B., et al. (2012) Composition and mineralogy of dark material deposits on Vesta. 43rd Lunar and Planetary Science Conference, March 19–23, The Woodlands, TX. LPI Contribution No. 1659, id. 1930.Google Scholar

Palomba, E., Longobardo, A., De Sanctis, M., et al. (2014) Composition and mineralogy of dark material units on Vesta. Icarus, 240, 58–72.Google Scholar

Palomba, E., Longobardo, A., De Sanctis, M., et al. (2015) Detection of new olivine-rich locations on Vesta. Icarus 258, 120–134.Google Scholar

Peplowski, P. N., Lawrence, D. J., Prettyman, T. H., et al. (2013) Compositional variability on the surface of 4 Vesta revealed through GRaND measurements of high‐energy gamma rays. Meteoritics & Planetary Science 48, 2252–2270.Google Scholar

Pieters, C. M. (1983) Strength of mineral absorption features in the transmitted component of near-infrared reflected light’ first results from RELAB. Journal of Geophysical Research 88, 9534–9544.Google Scholar

Pieters, C. M., Ammannito, E., Blewett, D. T., et al. (2012) Distinctive space weathering on Vesta from regolith mixing processes. Nature 491, 79–82.Google Scholar

Pieters, C. M., Taylor, L. A., & Noble, S. K. (2000) Space weathering on airless bodies: Resolving a mystery with lunar samples. Meteoritics & Planetary Science 35, 1101–1107.Google Scholar

Poulet, F., Ruesch, O., Langevin, Y., & Hiesinger, H. (2015) Modal mineralogy of the urface of Vesta: Evidence for ubiquitous olivine and identification of meteorite analogue. Icarus 253, 364–377.Google Scholar

Prettyman, T. H. (2014) Dawn GRaND map of hydrogen on Vesta, data set DAWN-A-GRAND-5-VESTA-HYDROGEN-MAP-V1.0. NASA Planetary Data System.Google Scholar

Prettyman, T. H., Mittlefehldt, D. W., Yamashita, N., et al. (2012) Elemental mapping by Dawn reveals exogenic H in Vesta’s regolith. Science 338, 242.Google Scholar

Prettyman, T. H., Mittlefehldt, D. W., Yamashita, N., et al. (2013) Neutron absorption constraints on the composition of 4 Vesta. Meteoritics & Planetary Science 48, 2211–2236.Google Scholar

Prettyman, T. H., Yamahita, Y., Reedy, R. C., et al. (2015) Concentrations of potassium and thorium within Vesta’s regolith. Icarus 259, 39–52.Google Scholar

Raymond, C. A., Russell, C. T., & McSween, H. Y. (2017) Dawn at Vesta: Paradigms and paradoxes. In Elkins-Tanton, L., & Weiss, B. (eds.), Planetesimals – Differentiation and Consequences for Planets. Cambridge: Cambridge University Press, pp. 321–340.Google Scholar

Rayner, J. T., Toomey, D. W., Onaka, P. M., et al. (2003) SpeX: A medium-resolution 0.8–5.5 micron spectrograph and imager for the NASA infrared telescope facility. The Publications of the Astronomical Society of the Pacific 115, 362–382.Google Scholar

Reddy, V., Le Corre, L., O’Brien, D. P., et al. (2012a) Delivery of dark material to Vesta via carbonaceous chondritic impacts [Erratum: 2013Icar..223.632R]. Icarus 221, 544–559.Google Scholar

Reddy, V., Li, J.-Y., Le Corre, L., et al. (2013) Comparing Dawn, Hubble Space Telescope, and ground-based interpretations of (4) Vesta. Icarus 226, 1103–1114.Google Scholar

Reddy, V., Nathues, A., & Gaffey, M. J. (2011) First fragment of Asteroid 4 Vesta’s mantle detected. Icarus 212, 175–179.Google Scholar

Reddy, V., Nathues, A., Le Corre, L., et al. (2012b) Color ad albedo heterogeneity of Vesta from Dawn. Science 336, 700–704.Google Scholar

Righter, K., & Drake, M. J. (1997) A magma ocean on Vesta: Core formation and petrogenesis of eucrites and diogenites. Meteoritics & Planetary Science 32, 929–944.Google Scholar

Rivkin, A. S., McFadden, L. A., Binzel, R. P., & Sykes, M. (2006) Rotationally-resolved spectroscopy of Vesta I: 2 4 μm region. Icarus 180, 464–472.Google Scholar

Rousseau, B., Raponi, A., Ciarniello, M., et al. (2019) Correction of the VIR-visible data set from the Dawn mission. Review of Scientific Instruments 90, 123110.Google Scholar

Ruesch, O., Hiesinger, H., De Sanctis, M., et al. (2014) Detections and geologic context of local enrichments in olivine on Vesta with VIR/Dawn data. Journal of Geophysical Research: Planets 119, 2078–2108.Google Scholar

Russell, C. T., & Raymond, C. A. (2011) The Dawn mission to Vesta and Ceres. Space Science Reviews 163, 3–23.Google Scholar

Russell, C. T., Raymond, C. A., Coradini, A., et al. (2012) Dawn at Vesta: Testing the protoplanetary paradigm. Science 336, 684.Google Scholar

Schenk, P., O’Brien, D. P., Marchi, S., et al. (2012) The geologically recent giant impact basins at Vesta’s south pole. Science 336, 694–697.Google Scholar

Schröder, S. E., Mottola, S., & Keller, H. (2013) Resolved photometry of Vesta reveals physical properties of Crater Regolith. Planetary and Space Science 85, 198–213.Google Scholar

Scott, E. R. D., Bottke, W. F., Marchi, S., & Delaney, J. S. (2014) How did mesosiderites form and do they come from Vesta or a Vesta-like body? 45th Lunar and Planetary Science Conference, March 17–21, The Woodlands, TX, 2260.Google Scholar

Spohn, T., Sohl, F., & Breuer, D. (1998) Mars. The Astronomy and Astrophysics Review 8, 181–235.Google Scholar

Sunshine, J. M., & Pieters, C. M. (1993) Estimating modal abundances from the spectra of natural and laboratory pyroxene mixtures using the modified Gaussian model. Journal of Geophysical Research 98, 9075–9087.Google Scholar

Sunshine, J. M., & Pieters, C. M. (1998) Determining the composition of olivine from reflectance spectroscopy. Journal of Geophysical Research 103, 13675–13688.Google Scholar

Sunshine, J. M., Pieters, C. M. & Pratt, S. F. (1990) Deconvolution of mineral absorption bands: An improved approach. Journal of Geophysical Research 95, 6955–6966.Google Scholar

Takeda, H. (1979) A layered-crust model of a Howardite parent body. Icarus 40, 455–470.Google Scholar

Takeda, H. (1997) Mineralogical records of early planetary processes on the HED parent body with reference to Vesta. Meteoritics & Planetary Science 32, 841–853.Google Scholar

Takeda, H., & Mori, H. (1985) The diogenite–eucrite links and the crystallization history of a crust of their parent body. Journal of Geophysical Research 90(Suppl.), C636–C648.Google Scholar

Taylor, L. A., Pieters, C. M., Keller, L. P., Morris, R. V., & McKay, D. S. (2001) Lunar mare soils: Space weathering and the major effects of surface-correlated nanophase Fe. Journal of Geophysical Research 106, 27985–28000.Google Scholar

Thangjam, G., Nathues, A., Mengel, K., et al. (2014) Olivine-rich exposures at Bellicia and Arruntia craters on (4) Vesta from Dawn FC. Meteoritics & Planetary Science 49, 1831–1850.Google Scholar

Thangjam, G., Nathues, A., Mengel, K., et al. (2016) Three-dimensional spectral analysis of compositional heterogeneity at Arruntia crater on (4) Vesta using Dawn FC. Icarus 267, 344–363.Google Scholar

Tosi, F., Frigeri, A., Combe, J.-P., et al. (2015) Mineralogical analysis of the Oppia quadrangle of asteroid (4) Vesta: Evidence for occurrence of moderate-reflectance hydrated minerals. Icarus 259, 129–149.Google Scholar

Turrini, D., Combe, J.-P., McCord, T. B., et al. (2014) The contamination of the surface of Vesta by impacts and the delivery of the dark material. Icarus 240, 86–102.Google Scholar

Turrini, D., Svetsov, V., Consolmagno, G., Sirono, S., & Pirani, S. (2016) Olivine on Vesta as exogenous contaminants brought by impacts: Constraints from modeling Vesta’s collisional history and from impact simulations. Icarus 280, 328–339.Google Scholar

Veeder, G. J., Jonson, T. V., & Matson, D L. (1975) Narrowband spectrophotometry of Vesta (abstract). Bulletin of the American Astronomical Society 7, 377.Google Scholar

Vernazza, P., Brunetto, R., Strazzulla, G., et al. (2006) Asteroid colors: A novel tool for magnetic field detection? The case of Vesta. Astronomy & Astrophysics 451, 43–46.Google Scholar

Veverka, J., Helfenstein, P., Lee, P., et al. (1996) Ida and Dactyl: Spectral and color variations. Icarus 120, 66–76.Google Scholar

Warren, P. H. (1997) MgO-FeO mass balance constraints and a more detailed model for the relationship between eucrites and diogenites. Meteoritics & Planetary Science 32, 945–963.Google Scholar

Wasson, J. T. (2013) Vesta and extensively melted asteroid: Why HED meteorites are probably not from Vesta. Earth and Planetary Science Letters 381, 138–146.Google Scholar

Yamashita, N., Prettyman, T. H., Mittlefehldt, D. W., et al. (2013) Distribution of iron on Vesta. Meteoritics & Planetary Science 48, 2237–2251.Google Scholar

Zambon, F., De Sanctis, M., Schröder, S., et al. (2014) Spectral analysis of the bright materials on the asteroid Vesta. Icarus 240, 73–85.Google Scholar

Zambon, F., Tosi, F., Carli, C., et al. (2016) Lithologic variation within bright material on Vesta revealed by linear spectral unmixing. Icarus 272, 16–31.Google Scholar

Zolensky, M. E., & Barrett, R. (1992) Compositional variations of olivines and pyroxenes in chondritic interplanetary dust particles. Meteoritics 27, 312.Google Scholar

Zolensky, M. E., Weisberg, M. K., Buchanan, P. C., & Mittlefehldt, D. W. (1996) Mineralogy of carbonaceous chondrite clasts in HED achondrites and the Moon, Meteoritics & Planetary Science 31, 518–537.Google Scholar

References

Ammannito, E., De Sanctis, M. C., Ciarniello, M., et al. (2016) Distribution of phyllosilicates on the surface of Ceres. Science, 353, aaf4279.Google Scholar

Beran, A. (2002) Infrared spectroscopy of micas. Reviews in Mineralogy and Geochemistry, 46, 351–369.Google Scholar

Berg, B. L., Cloutis, E. A., Beck, P., et al. (2016) Reflectance spectroscopy (0.35–8 μm) of ammonium-bearing minerals and qualitative comparison to Ceres-like asteroids. Icarus, 265, 218–237.Google Scholar

Binzel, R. P., & Xu, S. (1993) Chips off of Asteroid 4 Vesta: Evidence for the parent body of basaltic achondrite meteorites. Science, 260, 186–191.Google Scholar

Bishop, J. L., Banin, A., Mancinelli, R. L., & Klovstad, M. R. (2002) Detection of soluble and fixed NH₄⁺ in clay minerals by DTA and IR reflectance spectroscopy: A potential tool for planetary surface exploration. Planetary and Space Science, 50, 11.Google Scholar

Bishop, J. L., Lane, M. D., Dyar, M. D., & Brown, A. J. (2008) Reflectance and emission spectroscopy study of four groups of phyllosilicates: Smectites, kaolinite-serpentines, chlorites and micas. Clay Minerals, 43, 35–54.Google Scholar

Bowling, T. J., Ciesla, F. J., Davison, T. M., et al. (2019) Post-impact thermal structure and cooling timescales of Occator crater on asteroid 1 Ceres. Icarus, 320, 110–118.Google Scholar

Bowling, T. J., Johnson, B. C., Marchi, S., et al. (2020) An endogenic origin of cerean organics. Earth and Planetary Science Letters, 534, 116069.Google Scholar

Brown, M. E., & Rhoden, A. R. (2014) The 3 μm spectrum of Jupiter’s irregular satellite Himalia. The Astrophysical Journal, 793, L44.Google Scholar

Buczkowski, D. L., Schmidt, B. E., Williams, D. A., et al. (2016) The geomorphology of Ceres. Science, 353, aaf4332.Google Scholar

Bus, S. J., & Binzel, R. P. (2002a) Phase II of the small main-belt asteroid spectroscopic survey. The observations. Icarus, 158, 106.Google Scholar

Bus, S. J., & Binzel, R. P. (2002b) Phase II of the small main-belt asteroid spectroscopic survey. A feature-based taxonomy. Icarus, 158, 146.Google Scholar

Campins, H., Hargrove, K., Pinilla-Alonso, N., et al. (2010) Water ice and organics on the surface of the asteroid 24 Themis. Nature, 464, 1320–1321.Google Scholar

Carrozzo, F. G., De Sanctis, M. C., Raponi, A., et al. (2018) Nature, formation, and distribution of carbonates on Ceres. Science Advances, 4, e1701645.Google Scholar

Carrozzo, F. G., Raponi, A., De Sanctis, M. C., et al. (2016) Artifacts reduction in VIR/Dawn data. Review of Scientific Instruments, 87, 124501.Google Scholar

Castillo-Rogez, J. C., Neveu, M., McSween, H. Y., et al. (2018). Insights into Ceres’s evolution from surface composition. Meteoritics & Planetary Science, 53, 1820.Google Scholar

Castillo-Rogez, J. C., Neveu, M., Scully, J. E. C., et al. (2020) Ceres: Astrobiological target and possible ocean world. Astrobiology, 20, 269–291.Google Scholar

Chapman, C. R., & Gaffey, M. J. (1979) Reflectance spectra for 277 asteroids. In Gehrels, T., & Matthews, M. S. (eds.), Asteroids. Tucson: University of Arizona Press, pp. 655–687.Google Scholar

Chapman, C. R., McCord, T. B., & Johnson, T. V. (1973) Asteroid spectral reflectivities. The Astronomical Journal, 78, 126–140.Google Scholar

Chapman, C. R., & Salisbury, J. W. (1973) Comparisons of meteorite and asteroid spectral reflectivities. Icarus, 19, 507–522.Google Scholar

Ciarniello, M., De Sanctis, M. C., Ammannito, E., et al. (2017). Spectrophotometric properties of dwarf planet Ceres from the VIR spectrometer on board the Dawn mission. Astronomy and Astrophysics, 598, A130.Google Scholar

Clark, B. E., Hapke, B., Pieters, C., & Britt, D. (2002) Asteroid space weathering and regolith evolution. In Bottke, W. F. Jr., Cellino, A., Paolicchi, P., & Binzel, R. P. (eds.), Asteroids III. Tucson: University of Arizona Press, pp. 585–599.Google Scholar

Combe, J.-P., McCord, T. B., Tosi, F., et al. (2016) Detection of local H₂O exposed at the surface of Ceres. Science, 353, aaf3010.Google Scholar

Combe, J.-P., Raponi, A., Tosi, F., et al. (2019) Exposed H₂O-rich areas detected on Ceres with the dawn visible and infrared mapping spectrometer. Icarus, 318, 22–41.Google Scholar

Cruikshank, D. P., Tholen, D. J., Hartmann, W. K., Bell, J. F., & Brown, R. H. (1991) Three basaltic earth-approaching asteroids and the source of the basaltic meteorites. Icarus, 89, 1–13.Google Scholar

De Angelis, S., Ferrari, M., De Sanctis, M. C., et al. (2021) High-temperature VIS-IR spectroscopy of NH4-phyllosilicates. Journal of Geophysical Research: Planets, 126, e2020JE006696Google Scholar

De Sanctis, M. C., Ammannito, E., Carrozzo, F. G., et al. (2018) Ceres’s global and localized mineralogical composition determined by Dawn’s Visible and Infrared Spectrometer (VIR). Meteoritics & Planetary Science, 53, 1844.Google Scholar

De Sanctis, M. C., Ammannito, E., McSween, H. Y., et al. (2017) Localized aliphatic organic material on the surface of Ceres. Science, 355, 719–722.Google Scholar

De Sanctis, M. C., Ammannito, E., Raponi, A., et al. (2015) Ammoniated phyllosilicates with a likely outer Solar System origin on (1) Ceres. Nature, 528, 241–244.Google Scholar

De Sanctis, M. C., Ammannito, E., Raponi, A., et al. (2020) Fresh emplacement of hydrated sodium chloride on Ceres from ascending salty fluids. Nature Astronomy, 4, 786–793.Google Scholar

De Sanctis, M. C., Coradini, A., Ammannito, E., et al. (2011) The VIR spectrometer. Space Science Reviews, 163, 329–369.Google Scholar

De Sanctis, M. C., Raponi, A., Ammannito, E., et al. (2016) Bright carbonate deposits as evidence of aqueous alteration on (1) Ceres. Nature, 536, 54–57.Google Scholar

De Sanctis, M. C., Vinogradoff, V., Raponi, A., et al. (2019) Characteristics of organic matter on Ceres from VIR/Dawn high spatial resolution spectra. Monthly Notices of the Royal Astronomical Society, 482, 2407–2421.Google Scholar

dos Santos, R., Patel, M., Cuadros, J., & Martins, Z. (2016) Influence of mineralogy on the preservation of amino acids under simulated Mars conditions. Icarus, 277, 342.Google Scholar

Ehlmann, B. L., Hodyss, R., Bristow, T. F., et al. (2018) Ambient and cold-temperature infrared spectra and XRD patterns of ammoniated phyllosilicates and carbonaceous chondrite meteorites relevant to Ceres and other Solar System bodies. Meteoritics & Planetary Science, 53, 1884.Google Scholar

Farinella, P., Gonczi, R., Froeschle, C., & Froeschle, C. (1993) The injection of asteroid fragments into resonances. Icarus, 101, 174–187.Google Scholar

Farmer, V. C. (1974) The layer silicates. In Farmer, V. C. (ed.), The Infrared Spectra of Minerals, Monograph 4. London: Mineralogical Society, pp. 331–363.Google Scholar

Ferrari, M., De Angelis, S., De Sanctis, M. C., et al. (2019) Reflectance spectroscopy of ammonium-bearing phyllosilicates. Presented at EPSC-DPS Joint Meeting 2019, September 15–20, Geneva, id. EPSC-DPS2019–1864.Google Scholar

Formisano, M., Federico, C., De Sanctis, M. C., et al. (2018) Thermal stability of water ice in Ceres’ craters: The case of Juling crater. Journal of Geophysical Research (Planets), 123, 2445–2463.Google Scholar

Frigeri, A., De Sanctis, M. C., Ammannito, E., et al. (2019) The spectral parameter maps of Ceres from NASA/DAWN VIR data. Icarus, 318, 14–21.Google Scholar

Gaffey, M. J. (1976) Spectral reflectance characteristics of the meteorite classes. Journal of Geophysical Research, 81, 905–920.Google Scholar

Greenberg, J. M., Li, A., Mendoza-Gomez, C. X., et al. (1995) Approaching the interstellar grain organic refractory component. The Astrophysical Journal, 455, L177.Google Scholar

Hapke, B. (1993) Theory of Reflectance and Emittance Spectroscopy. New York: Cambridge University Press.Google Scholar

Hapke, B. (2012) Theory of Reflectance and Emittance Spectroscopy, 2nd ed. New York: Cambridge University Press.Google Scholar

Hendrix, A. R., Vilas, F., & Li, J.-Y. (2016) Ceres: Sulfur deposits and graphitized carbon. Geophysical Research Letters, 43, 8920.Google Scholar

Holm, N. G., Oze, C., Mousis, O., Waite, J. H., & Guilbert-Lepoutre, A. (2015) Serpentinization and the formation of H₂ and CH₄ on celestial bodies (planets, moons, comets). Astrobiology, 15, 587.Google Scholar

Hoyle, F., Wickramasinghe, N. C., Al-Mufti, S., Olavesen, A. H., & Wickramasinghe, D. T. (1982) Infrared spectroscopy over the 2.9–3.9 μm waveband in biochemistry and astronomy. Astrophysics and Space Science, 83, 405–409.Google Scholar

Kaplan, H. H., Milliken, R. E., & Alexander, C. M. O’D. (2018) New constraints on the abundance and composition of organic matter on Ceres. Geophysical Research Letters, 45, 5274–5282.Google Scholar

King, T. V. V., & Clark, R. N. (1989) Spectral characteristics of chlorites and Mg-serpentines using high-resolution reflectance spectroscopy. Journal of Geophysical Research, 94, 13997–14008.Google Scholar

King, T. V. V., Clark, R. N., Calvin, W. M., Sherman, D. M., & Brown, R. H. (1992) Evidence for ammonium-bearing minerals on Ceres. Science, 255, 1551–1553.Google Scholar

Krohn, M. D. (1987) Near-infrared detection of ammonium minerals. Geophysics, 52, 924.Google Scholar

Landis, M. E., Byrne, S., Combe, J.-P., et al. (2019) Water vapor contribution to Ceres’ exosphere from observed surface ice and postulated ice-exposing impacts. Journal of Geophysical Research: Planets, 124, 61–75.Google Scholar

Larson, H. P., Feierberg, M. A., Fink, U., & Smith, H. A. (1979) Remote spectroscopic identification of carbonaceous chondrite mineralogies: Applications to Ceres and Pallas. Icarus, 39, 257–271.Google Scholar

Lazzaro, D., Ferraz-Mello, S., & Fernández, J. A. (eds.) (2006) Asteroids, Comets, Meteors, IAU Symposium. New York: Cambridge University Press.Google Scholar

Le Guillou, C., Bernard, S., Brearley, A. J., & Remusat, L. (2014) Evolution of organic matter in Orgueil, Murchison and Renazzo during parent body aqueous alteration: In situ investigations. Geochimica et Cosmochimica Acta, 131, 368.Google Scholar

Lebofsky, L. A., Feierberg, M. A., Tokunaga, A. T., Larson, H. P., & Johnson, J. R. (1981) The 1.7- to 4.2-μm spectrum of asteroid 1 Ceres: Evidence for structural water in clay minerals. Icarus, 48, 453–459.Google Scholar

Li, J.-Y., McFadden, L. A., Parker, J. W., et al. (2006) Photometric analysis of 1 Ceres and surface mapping from HST observations. Icarus, 182, 143–160.Google Scholar

Li, J.-Y., Reddy, V., Nathues, A., et al. (2016) Surface albedo and spectral variability of Ceres. The Astrophysical Journal, 817, L22.Google Scholar

Li, J.-Y., Schröder, S. E., Mottola, S., et al. (2019) Spectrophotometric modeling and mapping of Ceres. Icarus, 322, 144–167.Google Scholar

Licandro, J., Campins, H., Kelley, M., et al. (2011) (65) Cybele: Detection of small silicate grains, water-ice, and organics. Astronomy and Astrophysics, 525, A34.Google Scholar

Longobardo, A., Palomba, E., Carrozzo, F. G., et al. (2019a) Mineralogy of the Occator quadrangle. Icarus, 318, 205–211.Google Scholar

Longobardo, A., Palomba, E., Galiano, A., et al. (2019b) Photometry of Ceres and Occator faculae as inferred from VIR/Dawn data. Icarus, 320, 97–109.Google Scholar

Marchi, S., Raponi, A., Prettyman, T. H., et al. (2019) An aqueously altered carbon-rich Ceres. Nature Astronomy, 3, 140–145.Google Scholar

McCollom, T. M., & Seewald, J. S. (2007) Abiotic synthesis of organic compounds in deep-sea hydrothermal environments. Chemical Reviews, 107, 382–401.Google Scholar

McCord, T. B., & Castillo-Rogez, J. C. (2018) Ceres’s internal evolution: The view after Dawn. Meteoritics & Planetary Science, 53, 1778–1792.Google Scholar

McCord, T. B., & Zambon, F. (2019) The surface composition of Ceres from the Dawn mission. Icarus, 318, 2.Google Scholar

Mennella, V., Baratta, G. A., Esposito, A., Ferini, G., & Pendleton, Y. J. (2003) The effects of ion irradiation on the evolution of the carrier of the 3.4 micron interstellar absorption band. The Astrophysical Journal, 587, 727.Google Scholar

Milliken, R. E., & Rivkin, A. S. (2009) Brucite and carbonate assemblages from altered olivine-rich materials on Ceres. Nature Geoscience, 2, 258–261.Google Scholar

Moroz, L. V., Arnold, G., Korochantsev, A. V., & Wäsch, R. (1998) Natural solid bitumens as possible analogs for cometary and asteroid organics: 1. Reflectance spectroscopy of pure bitumens. Icarus, 134, 253–268.Google Scholar

Nathues, A., Platz, T., Thangjam, G., et al. (2017). Evolution of Occator crater on (1) Ceres. The Astronomical Journal, 153, 112.Google Scholar

Nathues, A., Platz, T., Thangjam, G., et al. (2019) Occator crater in color at highest spatial resolution. Icarus, 320, 24–38.Google Scholar

Neesemann, A., van Gasselt, S., Schmedemann, N., et al. (2019) The various ages of Occator crater, Ceres: Results of a comprehensive synthesis approach. Icarus, 320, 60–82.Google Scholar

Orthous-Daunay, F.-R., Quirico, E., Beck, P., et al. (2013) Mid-infrared study of the molecular structure variability of insoluble organic matter from primitive chondrites. Icarus, 223, 534–543.Google Scholar

Palomba, E., Longobardo, A., De Sanctis, M. C., et al. (2019) Compositional differences among bright spots on the Ceres surface. Icarus, 320, 202–212.Google Scholar

Parker, J. W., Stern, S. A., Thomas, P. C., et al. (2002) Analysis of the first disk-resolved images of Ceres from ultraviolet observations with the Hubble Space Telescope. The Astronomical Journal, 123, 549.Google Scholar

Pearson, V. K., Sephton, M. A., Kearsley, A. T., et al. (2002) Clay mineral-organic matter relationships in the early Solar System. Meteoritics & Planetary Science, 37, 1829–1833.Google Scholar

Pendleton, Y. J., & Allamandola, L. J. (2002) The organic refractory material in the diffuse interstellar medium: Mid-infrared spectroscopic constraints. The Astrophysical Journal Supplement Series, 138, 75–98.Google Scholar

Pieters, C. M., Nathues, A., Thangjam, G., et al. (2018) Geologic constraints on the origin of red organic-rich material on Ceres. Meteoritics & Planetary Science, 53, 1983–1998.Google Scholar

Pieters, C. M., & Noble, S. K. (2016) Space weathering on airless bodies. Journal of Geophysical Research (Planets), 121, 1865.Google Scholar

Poch, O., Istiqomah, I., Quirico, E., et al. (2020) Ammonium salts are a reservoir of nitrogen on a cometary nucleus and possibly on some asteroids. Science, 367, aaw7462.Google Scholar

Poch, O., Jaber, M., Stalport, F., et al. (2015) Effect of nontronite smectite clay on the chemical evolution of several organic molecules under simulated martian surface ultraviolet radiation conditions. Astrobiology, 15, 221.Google Scholar

Postberg, F., Kempf, S., Schmidt, J., et al. (2009) Sodium salts in E-ring ice grains from an ocean below the surface of Enceladus. Nature, 459, 1098–1101.Google Scholar

Postberg, F., Schmidt, J., Hillier, J., Kempf, S., & Srama, R. (2011) A salt-water reservoir as the source of a compositionally stratified plume on Enceladus. Nature, 474, 620–622.Google Scholar

Prettyman, T. H., Feldman, W. C., McSween, H. Y., et al. (2011) Dawn’s gamma ray and neutron detector. Space Science Reviews, 163, 371–459.Google Scholar

Prettyman, T. H., Yamashita, N., Toplis, M. J., et al. (2017) Extensive water ice within Ceres’ aqueously altered regolith: Evidence from nuclear spectroscopy. Science, 355, 55–59.Google Scholar

Quick, L. C., Buczkowski, D. L., Ruesch, O., et al. (2019) A possible brine reservoir beneath Occator crater: Thermal and compositional evolution and formation of the Cerealia dome and Vinalia Faculae. Icarus, 320, 119–135.Google Scholar

Raponi, A., Carrozzo, F. G., Zambon, F., et al. (2019a) Mineralogical mapping of Coniraya quadrangle of the dwarf planet Ceres. Icarus, 318, 99–110.Google Scholar

Raponi, A., Ciarniello, M., Capaccioni, F., et al. (2020) Infrared detection of aliphatic organics on a cometary nucleus. Nature Astronomy, 4, 500.Google Scholar

Raponi, A., De Sanctis, M. C., Carrozzo, F. G., et al. (2019b) Mineralogy of Occator crater on Ceres and insight into its evolution from the properties of carbonates, phyllosilicates, and chlorides. Icarus, 320, 83–96.Google Scholar

Raponi, A., De Sanctis, M. C., Frigeri, A., et al. (2018) Variations in the amount of water ice on Ceres’ surface suggest a seasonal water cycle. Science Advances, 4, eaao3757.Google Scholar

Raymond, C. A., Ermakov, A. I., Castillo-Rogez, J. C., et al. (2020). Impact-driven mobilization of deep crustal brines on dwarf planet Ceres. Nature Astronomy, 4, 741–747.Google Scholar

Rivkin, A. S., & Emery, J. P. (2010) Detection of ice and organics on an asteroidal surface. Nature, 464, 1322.Google Scholar

Rivkin, A. S., Li, J.-Y., Milliken, R. E., et al. (2011) The surface composition of Ceres. Space Science Reviews, 163, 95–116.Google Scholar

Rivkin, A. S., Volquardsen, E. L., & Clark, B. E. (2006) The surface composition of Ceres: Discovery of carbonates and iron-rich clays. Icarus, 185, 563–567.Google Scholar

Roatsch, T., Kersten, E., Matz, K.-D., et al. (2016) Ceres survey atlas derived from Dawn Framing Camera images. Planetary and Space Science, 121, 115–120.Google Scholar

Roettger, E. E., & Buratti, B. J. (1994) Ultraviolet spectra and geometric albedos of 45 asteroids. Icarus, 112, 496.Google Scholar

Rousseau, B., De Sanctis, M. C., Raponi, A., et al. (2020) Correction of the VIR-visible dataset from the Dawn mission at Vesta. Review of Scientific Instruments, 91, 123102.Google Scholar

Ruesch, O., Platz, T., Schenk, P., et al. (2016) Cryovolcanism on Ceres. Science, 353, aaf4286.Google Scholar

Schröder, S. E., Mottola, S., Carsenty, U., et al. (2017) Resolved spectrophotometric properties of the Ceres surface from Dawn Framing Camera images. Icarus, 288, 201–225.Google Scholar

Schulte, M., & Shock, E. (2004) Coupled organic synthesis and mineral alteration on meteorite parent bodies. Meteoritics & Planetary Science, 39, 1577–1590.Google Scholar

Scully, J. E. C., Schenk, P. M., Castillo-Rogez, J. C., et al. (2020) The varied sources of faculae-forming brines in Ceres’ Occator crater emplaced via hydrothermal brine effusion. Nature Communications, 11, 3680.Google Scholar

Sierks, H., Keller, H. U., Jaumann, R., et al. (2011) The Dawn Framing Camera. Space Science Reviews, 163, 263–327.Google Scholar

Stein, N. T., Ehlmann, B. L., Palomba, E., et al. (2019) The formation and evolution of bright spots on Ceres. Icarus, 320, 188–201.Google Scholar

Takir, D., & Emery, J. P. (2012) Outer Main Belt asteroids: Identification and distribution of four 3-μm spectral groups. Icarus, 219, 641–654.Google Scholar

Takir, D., Emery, J. P., McSween, H. Y., et al. (2013) Nature and degree of aqueous alteration in CM and CI carbonaceous chondrites. Meteoritics & Planetary Science, 48, 1618–1637.Google Scholar

Tosi, F., Carrozzo, F. G., Zambon, F., et al. (2019) Mineralogical analysis of the Ac-H-6 Haulani quadrangle of the dwarf planet Ceres. Icarus, 318, 170–187.Google Scholar

Vernazza, P., Mothé-Diniz, T., Barucci, M. A., et al. (2005) Analysis of near-IR spectra of 1 Ceres and 4 Vesta, targets of the Dawn mission. Astronomy and Astrophysics, 436, 1113–1121.Google Scholar

Vinogradoff, V., Bernard, S., Le Guillou, C., & Remusat, L. (2018) Evolution of interstellar organic compounds under asteroidal hydrothermal conditions. Icarus, 305, 358–370.Google Scholar

Vinogradoff, V., Le Guillou, C., Bernard, S., et al. (2017) Paris vs. Murchison: Impact of hydrothermal alteration on organic matter in CM chondrites. Geochimica et Cosmochimica Acta, 212, 234.Google Scholar

Vu, T. H., Hodyss, R., Johnson, P. V., & Choukroun, M. (2017) Preferential formation of sodium salts from frozen sodium-ammonium-chloride-carbonate brines – Implications for Ceres’ bright spots. Planetary and Space Science, 141, 73–77.Google Scholar

Waite, Jr., J. H., Lewis, W. S., Magee, B. A., et al. (2009) Liquid water on Enceladus from observations of ammonia and ⁴⁰Ar in the plume. Nature, 460, 487–490.Google Scholar

Williams, D. A., Buczkowski, D. L., Mest, S. C., et al. (2018) Introduction: The geologic mapping of Ceres. Icarus, 316, 1–13.Google Scholar

Williams, L. B., Canfield, B., Voglesonger, K. M., & Holloway, J. R. (2005) Organic molecules formed in a “primordial womb”. Geology, 33, 913–916.Google Scholar

Zambon, F., Raponi, A., Tosi, F., et al. (2017) Spectral analysis of Ahuna Mons from Dawn mission’s visible-infrared spectrometer. Geophysical Research Letters, 44, 97–104.Google Scholar

Zolotov, M. Y. (2007) An oceanic composition on early and today’s Enceladus. Geophysical Research Letters, 34, L23203.Google Scholar

Zolotov, M. Y., & Shock, E. L. (2001) Composition and stability of salts on the surface of Europa and their oceanic origin. Journal of Geophysical Research, 106, 32815–32827.Google Scholar

References

Alexander, C. M. O’d., Bowden, R., Fogel, M. L., et al. (2012) The provenances of asteroids, and their contributions to the volatile inventory of the terrestrial planets. Science, 337, 721–723.Google Scholar

Alexander, C. M. O’d., Bowden, R., Fogel, M. L., & Howard, K. T. (2015) Carbonate abundances and isotopic compositions in chondrites. Meteoritics & Planetary Science, 50, 810–833.Google Scholar

Alexander, C. M. O’d., Cody, G. D., Kebukawa, Y., et al. (2014) Elemental, isotopic, and structural changes in Tagish Lake insoluble organic matter produced by parent body processes. Meteoritics & Planetary Science, 49, 503–525.Google Scholar

Anders, E., & Grevesse, N. (1989) Abundances of the elements: Meteoritic and solar. Geochimica et Cosmochimica Acta, 53, 197–214.Google Scholar

Armitage, P. J. (2020) Astrophysics of Planet Formation. Cambridge: Cambridge University PressGoogle Scholar

Bally, J., O’Dell, C. R., & McCaughrean, M. J. (2000) Disks, microjets, windblown bubbles, and outflows in the Orion nebula. The Astronomical Journal, 119, 2919–2959.Google Scholar

Beck, P., Eschrig, J., Potin, S., et al. (2021) “Water” abundance at the surface of C-complex main-belt asteroids. Icarus, 357, 114125.Google Scholar

Bland, M. T., Raymond, C. A., Schenk, P. M., et al. (2016) Composition and structure of the shallow subsurface of Ceres revealed by crater morphology. Nature Geoscience, 9, 538.Google Scholar

Bland, P. A., Jackson, M. D., Coker, R. F., et al. (2009) Why aqueous alteration in asteroids was isochemical: High porosity≠high permeability. Earth and Planetary Science Letters, 287, 559–568.Google Scholar

Bland, P. A., & Travis, B. J. (2017) Giant convecting mud balls of the early Solar System. Science Advances, 3, e1602514.Google Scholar

Bowling, T. J., Ciesla, F. J., Davison, T. M., et al. (2019) Post-impact thermal structure and cooling timescales of Occator crater on asteroid 1 Ceres. Icarus, 320, 110–118.Google Scholar

Bowling, T. J., Johnson, B. C., Marchi, S., et al. (2020) An endogenic origin of cerean organics. Earth and Planetary Science Letters, 534, 116069.Google Scholar

Brandt, J. C. (2014) Physics and chemistry of comets. In Spohn, T., Breuer, D., & Johnson, T. (eds.), Encyclopedia of the Solar System, 3rd ed. Amsterdam: Elsevier, pp. 683–703.Google Scholar

Brasser, R., & Mojzsis, S. J. (2020) The partitioning of the inner and outer Solar System by a structured protoplanetary disk. Nature Astronomy, 4, 492–499.Google Scholar

Brownlee, D., Tsou, P., Aléon, J., et al. (2006) Comet 81P/Wild 2 under a microscope. Science, 314, 1711.Google Scholar

Bu, C., Rodriguez Lopez, G., Dukes, C. A., et al. (2019) Stability of hydrated carbonates on Ceres. Icarus, 320, 136–149.Google Scholar

Cami, J., Bernard-Salas, J., Peeters, E., & Malek, S. E. (2010) Detection of C60 and C70 in a young planetary nebula. Science, 329, 1180.Google Scholar

Carrozzo, F. G., De Sanctis, M. C., Raponi, A., et al. (2018) Nature, formation, and distribution of carbonates on Ceres. Science Advances, 4, e1701645.Google Scholar

Castillo-Rogez, J. C., & McCord, T. B. (2010) Ceres’ evolution and present state constrained by shape data. Icarus, 205, 443–459.Google Scholar

Castillo-Rogez, J. C., Neveu, M., McSween, H. Y., et al. (2018) Insights into Ceres’s evolution from surface composition. Meteoritics & Planetary Science, 53, 1820–1843.Google Scholar

Castillo-Rogez, J. C., Neveu, M., Scully, J. E. C., et al. (2020) Ceres: Astrobiological target and possible ocean world. Astrobiology, 20, 269–291.Google Scholar

Chan, Q. H. S., Zolensky, M. E., Bodnar, R. J., Farley, C., & Cheung, J. C. H. (2017) Investigation of organo-carbonate associations in carbonaceous chondrites by Raman spectroscopy. Geochimica et Cosmochimica Acta, 201, 392–409.Google Scholar

Chan, Q. H. S., Zolensky, M. E., Kebukawa, Y., et al. (2018) Organic matter in extraterrestrial water-bearing salt crystals. Science Advances, 4, eaao3521.Google Scholar

Charnley, S. B. (1994) Chemistry of star‐forming cores. AIP Conference Proceedings, 312, 155–159.Google Scholar

Cronin, J. R., & Chang, S. (1993) Organic matter in meteorites: Molecular and isotopic analyses of the Murchison meteorite. In Greenberg, J. M., Mendoza-Gómez, C. X., & Pirronello, V. (eds.), The Chemistry of Life’s Origins Dordrecht: Springer Netherlands, pp. 209–258.Google Scholar

Daly, R. T., & Schultz, P. H. (2015) Predictions for impactor contamination on Ceres based on hypervelocity impact experiments. Geophysical Research Letters, 42, 7890–7898.Google Scholar

De Leuw, S., Rubin, A. E., & Wasson, J. T. (2010) Carbonates in CM chondrites: Complex formational histories and comparison to carbonates in CI chondrites. Meteoritics & Planetary Science, 45, 513–530.Google Scholar

De Sanctis, M. C., Ammannito, E., McSween, H. Y., et al. (2017) Localized aliphatic organic material on the surface of Ceres. Science, 355, 719–722.Google Scholar

De Sanctis, M. C., Ammannito, E., Raponi, A., et al. (2015) Ammoniated phyllosilicates with a likely outer Solar System origin on (1) Ceres. Nature, 528, 241–244.Google Scholar

De Sanctis, M. C., Ammannito, E., Raponi, A., et al. (2020) Fresh emplacement of hydrated sodium chloride on Ceres from ascending salty fluids. Nature Astronomy, 4, 786–793.Google Scholar

De Sanctis, M. C., Coradini, A., Ammannito, E., et al. (2011) The VIR spectrometer. Space Science Reviews, 163, 329–369.Google Scholar

De Sanctis, M. C., Raponi, A., Ammannito, E., et al. (2016) Bright carbonate deposits as evidence of aqueous alteration on (1) Ceres. Nature, 536, 54–57.Google Scholar

De Sanctis, M. C., Vinogradoff, V., Raponi, A., et al. (2018) Characteristics of organic matter on Ceres from VIR/Dawn high spatial resolution spectra. Monthly Notices of the Royal Astronomical Society, 482, 2407–2421.Google Scholar

Duprat, J., Dobrică, E., Engrand, C., et al. (2010) Extreme deuterium excesses in ultracarbonaceous micrometeorites from central Antarctic snow. Science, 328, 742.Google Scholar

Ehrenfreund, P., & Charnley, S. B. (2000) Organic molecules in the interstellar medium, comets, and meteorites: A voyage from dark clouds to the early Earth. Annual Review of Astronomy and Astrophysics, 38, 427–483.Google Scholar

Endreß, M., & Bischoff, A. (1996) Carbonates in CI chondrites: Clues to parent body evolution. Geochimica et Cosmochimica Acta, 60, 489–507.Google Scholar

Ermakov, A. I., Fu, R. R., Castillo-Rogez, J. C., et al. (2017) Constraints on Ceres’ internal structure and evolution from its shape and gravity measured by the Dawn spacecraft. Journal of Geophysical Research: Planets, 122, 2267–2293.Google Scholar

Flynn, G. J., Keller, L. P., Feser, M., Wirick, S., & Jacobsen, C. (2003) The origin of organic matter in the Solar System: evidence from the interplanetary dust particles. Geochimica et Cosmochimica Acta, 67, 4791–4806.Google Scholar

Fomenkova, M. N., Chang, S., & Mukhin, L. M. (1994) Carbonaceous components in the comet Halley dust. Geochimica et Cosmochimica Acta, 58, 4503–4512.Google Scholar

Fray, N., Bardyn, A., Cottin, H., et al. (2016) High-molecular-weight organic matter in the particles of comet 67P/Churyumov–Gerasimenko. Nature, 538, 72–74.Google Scholar

Fu, R. R., Ermakov, A. I., Marchi, S., et al. (2017) The interior structure of Ceres as revealed by surface topography. Earth and Planetary Science Letters, 476, 153–164.Google Scholar

Garvie, L. A. J., & Buseck, P. R. (2007) Prebiotic carbon in clays from Orgueil and Ivuna (CI), and Tagish Lake (C2 ungrouped) meteorites. Meteoritics & Planetary Science, 42, 2111–2117.Google Scholar

Grimm, R. E., & McSween, H. Y. (1993) Heliocentric zoning of the asteroid belt by aluminum-26 heating. Science, 259, 653.Google Scholar

Hasegawa, T. I., Herbst, E., & Leung, C. M. (1992) Models of gas-grain chemistry in dense interstellar clouds with complex organic molecules. The Astrophysical Journal Supplement Series, 82, 167–195.Google Scholar

Hendrix, A. R., Vilas, F., & Li, J.-Y. (2016a) Ceres: Sulfur deposits and graphitized carbon. Geophysical Research Letters, 43, 8920–8927.Google Scholar

Hendrix, A. R., Vilas, F., & Li, J.-Y. (2016b) The UV signature of carbon in the Solar System. Meteoritics & Planetary Science, 51, 105–115.Google Scholar

Holm, N. G., Oze, C., Mousis, O., Waite, J. H., & Guilbert-Lepoutre, A. (2015) Serpentinization and the formation of H2 and CH4 on celestial bodies (planets, moons, comets). Astrobiology, 15, 587–600.Google Scholar

Jessberger, E. K., Christoforidis, A., & Kissel, J. (1988) Aspects of the major element composition of Halley’s dust. Nature, 332, 691–695.Google Scholar

Kaplan, H. H., & Milliken, R. E. (2016) Reflectance spectroscopy for organic detection and quantification in clay-bearing samples: Effects of albedo, clay type, and water content. Clays and Clay Minerals, 64, 167–184.Google Scholar

Kaplan, H. H., Milliken, R. E., & Alexander, C. M. O. D. (2018) New constraints on the abundance and composition of organic matter on Ceres. Geophysical Research Letters, 45, 5274–5282.Google Scholar

Kaplan, H. H., Milliken, R. E., Alexander, C. M. O. D., & Herd, C. D. K. (2019) Reflectance spectroscopy of insoluble organic matter (IOM) and carbonaceous meteorites. Meteoritics & Planetary Science, 54, 1051–1068.Google Scholar

Kebukawa, Y., Ito, M., Zolensky, M. E., et al. (2019) A novel organic-rich meteoritic clast from the outer Solar System. Scientific Reports, 9, 3169.Google Scholar

Kretke, K. A., Bottke, W. F., Levinson, H. F., & Kring, D. A. (2017) Mixing of the asteroid belt due to the formation of the giant planets. Accrection: Building New Worlds, LPI Topical Conference, August 15–18, Lunar and Planetary Institute, Houston, TX, #2027.Google Scholar

Kurokawa, H., Ehlmann, B. L., De Sanctis, M. C., et al. (2020) A probabilistic approach to determination of Ceres’ average surface composition from Dawn VIR and GRaND data. Journal of Geophysical Research: Planets, n/a, e2020JE006606.Google Scholar

Lodders, K., & Fegley, B. Jr. (1998) The Planetary Scientist’s Companion. Oxford: Oxford University Press on Demand.Google Scholar

Marchi, S., Raponi, A., Prettyman, T. H., et al. (2019) An aqueously altered carbon-rich Ceres. Nature Astronomy, 3, 140–145.Google Scholar

McSween, H. Y., Emery, J. P., Rivkin, A. S., et al. (2017) Carbonaceous chondrites as analogs for the composition and alteration of Ceres. Meteoritics & Planetary Science, 53, 1793–1804.Google Scholar

Nuth, J. A., Johnson, N. M., & Manning, S. (2008) A self-perpetuating catalyst for the production of complex organic molecules in protostellar nebulae. Proceedings of the International Astronomical Union, 4, 403–408.Google Scholar

Pieters, C. M., Nathues, A., Thangjam, G., et al. (2018) Geologic constraints on the origin of red organic-rich material on Ceres. Meteoritics & Planetary Science, 53, 1983–1998.Google Scholar

Pizzarello, S., Davidowski, S. K., Holland, G. P., & Williams, L. B. (2013) Processing of meteoritic organic materials as a possible analog of early molecular evolution in planetary environments. Proceedings of the National Academy of Sciences (USA), 110, 15614.Google Scholar

Prettyman, T. H., Englert, P. A. J., & Yamashita, N. (2019a) Neutron, gamma-ray, and X-ray spectroscopy: Theory and applications. In Bishop, J. L., Bell, J. F., & Moersch, J.E. (eds.), Remote Compositional Analysis. Cambridge: Cambridge University Press, pp. 191–238.Google Scholar

Prettyman, T. H., Feldman, W. C., McSween, H. Y. Jr., et al. (2011) Dawn’s gamma ray and neutron detector. Space Science Reviews, 163, 371–459.Google Scholar

Prettyman, T. H., Mittlefehldt, D. W., Yamashita, N., et al. (2012) Elemental mapping by Dawn reveals exogenic H in Vesta’s regolith. Science, 338, 242–246.Google Scholar

Prettyman, T. H., Yamashita, N., Ammannito, E., et al. (2019b) Elemental composition and mineralogy of Vesta and Ceres: Distribution and origins of hydrogen-bearing species. Icarus, 318, 42–55.Google Scholar

Prettyman, T. H., Yamashita, N., & McSween, H. Y. (2018) Carbon on Ceres: Implications for origins and interior evolution. 49th Lunar and Planetary Science Conference, March 19–23, The Woodlands, TX, #1151.Google Scholar

Prettyman, T. H., Yamashita, N., Toplis, M. J., et al. (2017) Extensive water ice within Ceres’ aqueously altered regolith: Evidence from nuclear spectroscopy. Science, 355, 55–59.Google Scholar

Raponi, A., De Sanctis, M. C., Carrozzo, F. G., et al. (2019) Mineralogy of Occator crater on Ceres and insight into its evolution from the properties of carbonates, phyllosilicates, and chlorides. Icarus, 320, 83–96.Google Scholar

Raponi, A., De Sanctis, M. C., Carrozzo, F. G., et al. (2021) Organic material on Ceres: Insights from visible and infrared space observations. Life, 11, 9.Google Scholar

Raymond, C. A., Ermakov, A. I., Castillo-Rogez, J. C., et al. (2020) Impact-driven mobilization of deep crustal brines on dwarf planet Ceres. Nature Astronomy, 4, 741–747.Google Scholar

Raymond, S. N., & Izidoro, A. (2017) Origin of water in the inner solar system: Planetesimals scattered inward during Jupiter and Saturn’s rapid gas accretion. Icarus, 297, 134–148.Google Scholar

Riebe, M. E. I., Foustoukos, D. I., Alexander, C. M. O. D., et al. (2020) The effects of atmospheric entry heating on organic matter in interplanetary dust particles and micrometeorites. Earth and Planetary Science Letters, 540, 116266.Google Scholar

Rivkin, A. S., Volquardsen, E. L., & Clark, B. E. (2006) The surface composition of Ceres: Discovery of carbonates and iron-rich clays. Icarus, 185, 563–567.Google Scholar

Rubin, A. E., Zolensky, M. E., & Bodnar, R. J. (2002) The halite-bearing Zag and Monahans (1998) meteorite breccias: Shock metamorphism, thermal metamorphism and aqueous alteration on the H-chondrite parent body. Meteoritics & Planetary Science, 37, 125–141.Google Scholar

Ruesch, O., Genova, A., Neumann, W., et al. (2019) Slurry extrusion on Ceres from a convective mud-bearing mantle. Nature Geoscience, 12, 505–509.Google Scholar

Ruesch, O., Platz, T., Schenk, P., et al. (2016) Cryovolcanism on Ceres. Science, 353, aaf4286.Google Scholar

Sahijpal, S., Goswami, J. N., Davis, A. M., Grossman, L., & Lewis, R. S. (1998) A stellar origin for the short-lived nuclides in the early solar system. Nature, 391, 559–561.Google Scholar

Schulte, M., & Shock, E. (2004) Coupled organic synthesis and mineral alteration on meteorite parent bodies. Meteoritics & Planetary Science, 39, 1577–1590.Google Scholar

Scott, E. R. D., Krot, A. N., & Sanders, I. S. (2018) Isotopic dichotomy among meteorites and its bearing on the protoplanetary disk. The Astrophysical Journal, 854, 164.Google Scholar

Sephton, M. A. (2002) Organic compounds in carbonaceous meteorites. Natural Product Reports, 19, 292–311.Google Scholar

Sierks, H., Keller, H. U., Jaumann, R., et al. (2011) The Dawn Framing Camera. Space Science Reviews, 163, 263–327.Google Scholar

Thomas, K. L., Blanford, G. E., Keller, L. P., Klöck, W., & McKay, D. S. (1993) Carbon abundance and silicate mineralogy of anhydrous interplanetary dust particles. Geochimica et Cosmochimica Acta, 57, 1551–1566.Google Scholar

Travis, B. J., Bland, P. A., Feldman, W. C., & Sykes, M. V. (2018) Hydrothermal dynamics in a CM-based model of Ceres. Meteoritics & Planetary Science, 53, 2008–2032.Google Scholar

Vokrouhlický, D., Bottke, W. F., & Nesvorný, D. (2016) Capture of trans-Neptunian planetesimals in the main asteroid belt. The Astronomical Journal, 152, 39.Google Scholar

Warren, P. H. (2011) Stable-isotopic anomalies and the accretionary assemblage of the Earth and Mars: A subordinate role for carbonaceous chondrites. Earth and Planetary Science Letters, 311, 93–100.Google Scholar

Weisberg, M. K., McCoy, T. J., & Krot, A. N. (2006) Systematics and evaluation of meteorite classification. In Lauretta, D. S., & McSween, H. Y. Jr. (eds.), Meteorites and the Early Solar System II. Tucson: University of Arizona Press, pp. 19–52.Google Scholar

Zolensky, M. E., Mittlefehldt, D. W., Lipschutz, M. E., et al. (1997) CM chondrites exhibit the complete petrologic range from type 2 to 1. Geochimica et Cosmochimica Acta, 61, 5099–5115.Google Scholar

Zolotov, M. Y. (2017) Aqueous origins of bright salt deposits on Ceres. Icarus, 296, 289–304.Google Scholar

References

Ammannito, E., DeSanctis, M. C., Ciarniello, M., et al. (2016) Distribution of phyllosilicates on the surface of Ceres. Science, 353, aaf4279.Google Scholar

Bauer, J. M., Roush, R. L., Geballe, T. R., et al. (2002) The near-infrared spectrum of Miranda. Icarus, 158, 178–190.Google Scholar

Berg, B. L., Cloutis, E. A., Beck, P., et al. (2016) Reflectance spectroscopy (0.35–8 μm) of ammonium-bearing minerals and qualitative comparison to Ceres-like asteroid. Icarus, 265, 218–237.Google Scholar

Bishop, J. L., Banina, A., Mancinelli, R. L., & Klovstad, M. R. (2002) Detection of soluble and fixed NH4+ in clay minerals by DTA and IR reflectance spectroscopy: A potential tool for planetary surface exploration. Planetary and Space Science, 50, 11–19.Google Scholar

Brown, M. E., & Calvin, W. M. (2000) Evidence for crystalline water and ammonia ices on Pluto’s satellite Charon. Science, 287, 107–109.Google Scholar

Brown, M. E., Schaller, E. L., & Fraser, W. C. (2011) A hypothesis for the color diversity of the Kuiper Belt. Astrophysics Journal Letters, 739, L60–L64.Google Scholar

Bruno, T. J., & Svoronos, P. D. N. (1989) CRC Handbook of Basic Tables for Chemical Analysis. Boca Raton, FL: CRC Press.Google Scholar

Busigny, V., Cartigny, P., Philippot, P., & Javoy, M. (2003) Ammonium quantification in muscovite by infrared spectroscopy. Chemical Geology, 198, 21–31.Google Scholar

Callahan, M. P., Smith, K., Cleaves, H., et al. (2011) Carbonaceous meteorites contain a wide range of extraterrestrial nucleobases. Proceedings of the National Acadamy of Sciences (USA), 108, 13995–13998.Google Scholar

Carrozzo, F. G., De Sanctis, M. C., Raponi, A., et al. (2018) Nature, formation, and distribution of carbonates on Ceres. Science Advances, 4, e1701645.Google Scholar

Castillo-Rogez, J. C., & McCord, T. B. (2010) Ceres’ evolution and present state constrained by shape data. Icarus, 205, 443–459.Google Scholar

Castillo-Rogez, J., Neveu, M., McSween, H. Y., et al. (2018) Insights into Ceres’s evolution from surface composition. Meteoritics & Planetary Science, 53, 1820–1843.Google Scholar

Castillo-Rogez, J. C., Neveu, M., Scully, J. E. C., et al. (2020) Ceres: Astrobiological target and possible ocean world. Astrobiology, 20, 269–291.Google Scholar

Ciarniello, M., De Sanctis, M. C., Ammannito, E., et al. (2017) Spectrophotometric properties of dwarf planet Ceres from the VIR spectrometer on board the Dawn mission. Astronomy & Astrophysics, 598, A130.Google Scholar

Chourabi, B., & Fripiat, J. J. (1981). Determination of tetrahedral substitutions and interlayer surface heterogeneity from vibrational spectra of ammonium in smectites. Clays and Clay Minerals, 29, 260–268.Google Scholar

Dalle Ore, C. M., Cruikshank, D. P., Protopapa, S. et al. (2019) Detection of ammonia on Pluto’s surface in a region of geologically recent tectonism. Science Advances, 5, eaav5731.Google Scholar

De Sanctis, M. C., Ammannito, E., Raponi, A., et al. (2015) Ammoniated phyllosilicates with a likely outer Solar System origin on (1) Ceres. Nature, 528, 241–244.Google Scholar

De Sanctis, M. C., Ammannito, E., Raponi, A., et al. (2020) Fresh emplacement of hydrated sodium chloride on Ceres from ascending salty fluids. Nature Astronomy, 4, 786–793.Google Scholar

De Sanctis, M. C., Coradini, A., Ammannito, E., et al. (2011) The VIR spectrometer. Space Science Reviews, 163, 329–369.Google Scholar

De Sanctis, M. C., Frigeri, A., Ammannito, E., et al. (2019) Ac-H-11 Sintana and Ac-H-12 Toharu quadrangles: Assessing the large and small scale heterogeneities of Ceres’ surface. Icarus, 318, 230–240.Google Scholar

De Sanctis, M. C., Raponi, A., Ammannito, E., et al. (2016) Bright carbonate deposits as evidence of aqueous alteration on (1) Ceres. Nature, 536, 1–4.Google Scholar

Dodson-Robinson, S. E., Willacy, K., Bodenheimer, P., Turner, N. J., & Beichman, C. A. (2009) Ice lines, planetesimal composition and solid surface density in the solar nebula. Icarus, 200, 672–693.Google Scholar

Farmer, V. C., & Russell, J. D. (1967) Infrared absorption spectrometry in clay studies. Clays and Clay Minerals, 15, 121–142.Google Scholar

Ferrari, M., De Angelis, S., De Sanctis, M. C., et al. (2019) Reflectance spectroscopy of ammonium-bearing phyllosilicates. Icarus, 321, 522–530.Google Scholar

Fox, V. K., Kupper, R. J., Ehlmann, B. L., et al. (2021) Synthesis and characterization of Fe(III)-Fe(II)-Mg-Al smectite solid solutions and implications for planetary science. American Mineralogist, 106, 964–982.Google Scholar

Fu, R. R., Ermakov, A. I., Marchi, S., et al. (2017) The interior structure of Ceres as revealed by surface topography. Earth and Planetary Science Letters, 476, 153–164.Google Scholar

Honma, H. (1996) High ammonium contents in the 3800 Ma Isua supracrustal rocks, central West Greenland. Geochimica et Cosmochimica Acta, 60, 2173–2178.Google Scholar

Itihara, Y., & Honma, H. (1979) Ammonium in biotite from metamorphic and granitic rocks of Japan. Geochimica et Cosmochimica Acta, 43, 503–509.Google Scholar

Jewitt, D. C., & Luu, J. (2004) Crystalline water ice on the Kuiper belt object (50000) Quaoar. Nature, 432, 731–733.Google Scholar

Kargel, J. S. (1992) Ammonia-water volcanism on icy satellites: Phase relations at 1 atmosphere. Icarus, 100, 556–574.Google Scholar

King, T. V. V., Clark, R. N., Calvin, W. M., Sherman, D. M., & Brown, R. H. (1992) Evidence for ammonium-bearing minerals on Ceres. Science, 255, 1551–1553.Google Scholar

Krohn, M. D., & Altaner, S. P. (1987) Near infrared detection of ammonium minerals. Geophysics, 52, 924–930.Google Scholar

Kurokawa, H., Ehlmann, B. L., De Sanctis, M. C., (2020) A probabilistic approach to determination of Ceres’ average surface composition from Dawn visible-infrared mapping spectrometer and gamma ray and neutron detector data. Journal of Geophysical Research: Planets, 125, e06606.Google Scholar

Lebofsky, L. (1978) Asteroid 1 Ceres: Evidence for water of hydration. Monthly Notices of the Royal Astronomical Society, 182, 17P-21P.Google Scholar

Lebofsky, L., Feierberg, M., Tokunaga, A., Larson, H., & Johnson, J. (1981) The 1.7–4.2 μm spectrum of asteroid 1 Ceres: Evidence for structural water in clay minerals. Icarus, 48, 453–459.Google Scholar

Li, J.-Y., Reddy, V., Nathues, A., et al. (2016) Surface albedo and spectral variability of Ceres. The Astrophysical Journal Letters, 817, L22.Google Scholar

Marchi, S., Ermakov, A. I., Raymond, C. A., et al. (2016) The missing large impact craters on Ceres. Nature Communications, 7, 12257.Google Scholar

Matson, D. L., Castillo, J. C., Lunine, J., & Johnson, T. V. (2007) Enceladus’ plume: Compositional evidence for a hot interior. Icarus, 187, 569–573.Google Scholar

McCord, T., & Sotin, C. (2005) Ceres: Evolution and current state. Journal of Geophysical Research, 110, E05009.Google Scholar

McKinnon, W. B. (2008) Could Ceres be a refugee from the Kuiper Belt? Asteroids, Comets, Meteors Conference, July 14–18, Baltimore, MD, No 1405, abstract #8389.Google Scholar

Milliken, R. E., & Rivkin, A. S. (2009) Brucite and carbonate assemblages from altered olivine-rich materials on Ceres. Nature Geoscience, 2, 258–261.Google Scholar

Mookherjee, M., Redfern, S. A. T., Zhang, M., & Harlov, D. E. (2002) Orientational order–disorder of N(D,H)4+ in tobelite. American Mineralogist, 87, 1686–1691.Google Scholar

Neesemann, A., van Gasselt, S., Schmedemann, N., et al. (2019) The various ages of Occator crater, Ceres: Results of a comprehensive synthesis approach. Icarus, 320, 60–82.Google Scholar

Papineau, D., Mojzsis, S. J., Karhu, J. A., & Marty, B. (2005) Nitrogen isotopic composition of ammoniated phyllosilicates: Case studies from precambrian metamorphosed sedimentary rocks. Chemical Geology, 216, 37–58.Google Scholar

Pizzarello, S., & Williams, L. B. (2012) Ammonia in the early Solar System: An account from carbonaceous meteorites. The Astrophysical Journal, 749, 161.Google Scholar

Prettyman, T. H., Yamashita, N., Toplis, M. J., et al. (2017) Extensive water ice within Ceres’ aqueously altered regolith: Evidence from nuclear spectroscopy. Science, 355, 55–59.Google Scholar

Raymond, C. A., Ermakov, A. I., Castillo-Rogez, J. C., et al. (2020) Impact-driven mobilization of deep crustal brines on dwarf planet Ceres. Nature Astronomy, 4, 741–747.Google Scholar

Reddy, V., Li, J.-Y., Gary, B. L., et al. (2015) Photometric properties of Ceres from telescopic observations using Dawn Framing Camera color filters. Icarus, 260, 332–345.Google Scholar

Rivkin, A. S., Volquardsen, E. L., & Clark, B. E. (2006) The surface composition of Ceres: Discovery of carbonates and iron-rich clays. Icarus, 185, 563–567.Google Scholar

Rivkin, A. S., Howell, E. S., & Emery, J. P. (2019) Infrared spectroscopy of large, low‐albedo asteroids: Are Ceres and Themis archetypes or outliers? Journal of Geophysical Research: Planets, 124, 1393–1409.Google Scholar

Robinson, J. W. (1974) CRC Handbook of Spectroscopy. Boca Raton, FL: CRC Press.Google Scholar

Rognini, E., Capria, M. T., Tosi, F., et al. (2020) High thermal inertia zones on Ceres from Dawn data. Journal of Geophysical Research: Planets, 125, e05733.Google Scholar

Russell, C. T., & Raymond, C. A. (2011) The Dawn mission to Vesta and Ceres. Space Science Reviews 163, 3–23.Google Scholar

Schenk, P., Scully, J., Buczkowski, D., et al. (2020) Impact heat driven volatile redistribution at Occator crater on Ceres as a comparative planetary process. Nature Communications, 11, 3679.Google Scholar

Silverstein, R. M., Bassler, G. C., & Morrill, T. C. (1991) Spectrometric Identification of Organic Compounds, 5th ed. New York: Wiley.Google Scholar

Srasra, E., Bergaya, F., & Fripiat, J. J. (1994) Infrared spectroscopy study of tetrahedral and octahedral substitutions in an interstratified illite‐smectite clay. Clays and Clay Minerals, 42, 237–241.Google Scholar

Stein, N. T., Ehlmann, B. L., Palomba, E., et al. (2019) The formation and evolution of bright spots on Ceres. Icarus, 320, 188–201.Google Scholar

Stephan, K., Jaumann, R., Zambon, F., et al. (2019) Ceres’ impact craters – Relationships between surface composition and geology. Icarus, 318, 56–74.Google Scholar

Takir, D., & Emery, J. P. (2012) Outer Main Belt asteroids: Identification and distribution of four 3-mm spectral groups. Icarus, 219, 641–654.Google Scholar

Thomas, E. C., Vu, T. H., Hodyss, R., et al. (2019) Kinetic effect on the freezing of ammonium-sodium-carbonate-chloride brines and implications for the origin of Ceres’ bright spots. Icarus, 320, 150–158.Google Scholar

Usui, F., Hasegawa, S., Ootsubo, T., & Onaka, T. (2019) AKARI/IRC near-infrared asteroid spectroscopic survey: AcuA-spec. Publications: Astronomical Society of Japan, 71.Google Scholar

Vedder, T. V. (1965) Ammonium in muscovite. Geochimica et Cosmochimica Acta, 29, 221–228.Google Scholar

Waite, J. H., Jr., Lewis, W. S., Magee, B. A., et al. (2009) Liquid water on Enceladus from observations of ammonia and 40Ar in the plume. Nature, 460, 487–490.Google Scholar

Zolotov, M. Y. (2017) Aqueous origins of bright salt deposits on Ceres. Icarus, 296, 289–304.Google Scholar

References

Ammannito, E., De Sanctis, M. C., Ciarniello, M., et al. (2016) Distribution of phyllosilicates on the surface of Ceres. Science, 353, aaf4279.Google Scholar

Bland, M. T. (2013) Predicted crater morphologies on Ceres: Probing internal structure and evolution. Icarus, 226, 510–521.Google Scholar

Bland, M. T., Raymond, C. A., Schenk, P. M., et al. (2016) Composition and structure of the shallow subsurface of Ceres revealed by crater morphology. Nature Geoscience, 9, 538–542.Google Scholar

Bland, M. T., Sizemore, H. G., Buczkowski, D. L., et al. (2018) Why is Ceres lumpy? Surface deformation induced by solid-state subsurface flow. 49th Lunar and Planetary Science Conference, March, Houston, TX, Abstract #1627.Google Scholar

Bowling, T. J., Ciesla, F. J., Davison, T. M., et al. (2019) Post-impact thermal structure and cooling timescales of Occator crater on asteroid 1 Ceres. Icarus, 320, 110–118.Google Scholar

Boyce, J., Wilson, L., Mouginis-Mark, P. J., Hamilton, C. W., & Tornabene, L. L. (2012) Origin of small pits in martian impact craters. Icarus, 221, 262–275.Google Scholar

Buczkowski, D. L., Schmidt, B. E., Williams, D. A., et al. (2016) The geomorphology of Ceres. Science, 353.Google Scholar

Buczkowski, D. L., Scully, J. E. C., Quick, L., et al. (2019) Tectonic analysis of fracturing associated with Occator crater. Icarus, 320, 49–59.Google Scholar

Buczkowski, D. L., Sizemore, H. G., Bland, M. T., et al. (2018) Floor-fractured craters on Ceres and implications for interior processes. Journal of Geophysical Research, 123, 3188–3204.Google Scholar

Buczkowski, D. L., Williams, D. A., Scully, J. E. C., et al. (2017) The geology of the Occator quadrangle of dwarf planet Ceres: Floor-fractured craters and other geomorphic evidence of cryomagmatism, Icarus, 316, 128–139.Google Scholar

Castillo-Rogez, J. C., & McCord, T. B. (2010) Ceres’ evolution and present state constrained by shape data. Icarus, 205, 443–459.Google Scholar

Castillo-Rogez, J. C., Neveu, M., Scully, J. E. C., et al. (2020) Ceres: Astrobiological target and possible ocean world. Astrobiology, 20, 269–291.Google Scholar

Chamberlain, M. A., Sykes, M. V., & Esquerdo, G. A. (2007) Ceres lightcurve analysis – Period determination. Icarus, 188, 451–456.Google Scholar

Chilton, H. T., Schmidt, B. E., Duarte, K., et al. (2019) Landslides on Ceres: Inferences into ice content and layering in the upper crust. Journal of Geophysical Research, 124, 1512–1524.Google Scholar

Combe, J.-Ph., McCord, T. B., Tosi, F., et al. (2016) Detection of local H2O exposed at the surface of Ceres. Science, 353, aaf3010.Google Scholar

Combe, J.-Ph., Raponi, A., Zambon, F., et al. (2019) Exposed H₂O-rich areas detected on Ceres with the Dawn visible and infrared mapping spectrometer. Icarus, 318, 22–41.Google Scholar

Crown, D. A., Sizemore, H. G., Yingst, R. A., et al. (2018) Geologic mapping of the Urvara and Yalode Qudrangles of Ceres. Icarus, 316, 167–190.Google Scholar

De Sanctis, M. C., Ammannito, E., Capria, M. T., et al. (2012) Spectroscopic characterization of mineralogy and its diversity across Vesta. Science, 336, 697–700.Google Scholar

De Sanctis, M. C., Ammannito, E., Carrozzo, F. G., et al. (2018) Ceres’ global and localized mineralogical composition determined by Dawn’s Visible and Infrared Spectrometer (VIR). Meteoritic & Planetary Science, 53, 1844–1865.Google Scholar

De Sanctis, M. C., Ammannito, E., McSween, H., et al. (2017) Localized aliphatic organic material on the Surface of Ceres. Science, 355, 719–722.Google Scholar

De Sanctis, M. C., Ammannito, E., Raponi, A., et al. (2015) Ammoniated phyllosilicates with a likely outer Solar System origin on (1) Ceres. Nature, 528, 241–244.Google Scholar

De Sanctis, M. C., Ammannito, E., Raponi, A., et al. (2020) Fresh emplacement of hydrated sodium chloride on Ceres from ascending salty fluids. Nature Astronomy, 4, 786–793.Google Scholar

De Sanctis, M. C., Raponi, A., Ammannito, E., et al. (2016) Bright carbonate deposits as evidence of aqueous alteration on (1) Ceres. Nature, 536, 54–57.Google Scholar

Denevi, B. W., Blewett, D. T., Buczkowski, D. L., et al. (2012) Pitted terrain on Vesta and implications for the presence of volatiles. Science, 338, 246–249.Google Scholar

Duarte, K., Schmidt, B. E., Chilton, H., et al. (2019) Landslides on Ceres: Diversity and geologic context. Journal of Geophysical Research, 124, 3329–3343.Google Scholar

Frigeri, A., Schmedemann, N., Williams, D. A., et al. (2018) The geology of the Nawish quadrangle of Ceres: The rim of an ancient basin. Icarus, 316, 114–127.Google Scholar

Greeley, R. (2013) Introduction to Planetary Geomorphology. New York: Cambridge University Press.Google Scholar

Hendrix, A. R., Hurford, T. A., Barge, L. M., et al. (2019) The NASA roadmap to ocean worlds. Astrobiology, 19, 1.Google Scholar

Hesse, M. A., & Castillo-Rogez, J. C. (2018) Thermal evolution of the impact-induced cryomagma chamber beneath Occator crater on Ceres. Geophysical Research Letters, 46, 1213–1221.Google Scholar

Hiesinger, H., Marchi, S., Schmedemann, N., et al. (2016) Cratering on Ceres: Implications for its crust and evolution. Science, 353, 4759.Google Scholar

Hughson, K., Russell, C. T., Schmidt, B. E., et al. (2019) Fluidized appearing ejecta on Ceres: Implications for the mechanical properties, frictional properties, and composition of its shallow subsurface. Journal of Geophysical Research, 124, 1819–1839.Google Scholar

Hughson, K., Russell, C. T., Williams, D. A., et al. (2018) The Ac-H-5 (Fejokoo) quadrangle of Ceres: Geologic map and geomorphological evidence for ground ice mediated surface processes. Icarus, 316, 63–83.Google Scholar

Jaumann, R., Williams, D. A., Buczkowski, D. L., et al. (2012) Vesta’s shape and morphology. Science, 336, 687–690.Google Scholar

Jaumann, R., Preusker, F., Krohn, K., et al. (2017) Topography and geomorphology of the interior of Occator crater on Ceres. 48th Lunar and Planetary Science Conference, March, Houston, TX, Abstract #1440.Google Scholar

Jones, K.B., Head, J., Pappalardo, R. T., & Moore, J. M. (2003) Morphology and origin of palimpsests on Ganymede from Galileo observations. Icarus, 164, 197–212.Google Scholar

Krohn, K., Jaumann, R., Otto, K. A., et al. (2018) The unique geomorphology and structural geology of the Haulani crater of dwarf planet Ceres as revealed by geological mapping of equatorial quadrangle Ac-6 Haulani. Icarus, 316, 84–98.Google Scholar

Krohn, K., Jaumann, R., Stephan, K., et al. (2016) Cryogenic flow features on Ceres: Implications for crater-related cryovolcanism on dwarf planet Ceres. Geophysical Research Letters, 43, 11994–12003.Google Scholar

Lebofsky, L. A., Sykes, M. V., Tedesco, E. F., et al. (1986) A refined ‘standard’ thermal model for asteroids based on observations of 1 Ceres and 2 Pallas. Icarus, 68, 239–251.Google Scholar

Li, J.-Y., Mcfadden, L. A., Parker, J. W., et al. (2006) Photometric analysis of 1 Ceres and surface mapping from HST observations. Icarus, 182, 143–160.Google Scholar

Marchi, S., Ermakov, A., Raymond, C. A., et al. (2016) The missing large impact craters on Ceres. Nature Communications, 7, 12257.Google Scholar

Marchi, S., McSween, H. Y., O’Brien, D. P., et al. (2012) The violent collisional history of asteroid 4 Vesta. Science, 336, 690–693.Google Scholar

McCord, T. B., Adams, J. B., & Johnson, T. V. (1970) Asteroid Vesta: Spectral reflectivity and compositional implications. Science, 168, 1445–1447.Google Scholar

McCord, T. B., Castillo-Rogez, J. C., & Rivkin, A. (2011) Ceres: Its origin, evolution and structure and Dawn’s potential contribution. Space Science Reviews, 163, 63–76.Google Scholar

McCord, T. B., & Sotin, C. (2005) Ceres: Evolution and current state. Journal of Geophysical Research, 110, E05009.Google Scholar

Mest, S. C., Crown, D. A., Berman, D. C., et al. (2018) The HAMO-based global geologic map and chronostratigraphy of Ceres. 49th Lunar and Planetary Science Conference, March, Houston, TX, Abstract #2730.Google Scholar

Michalak, G. (2000) Determination of asteroid masses – I. (1) Ceres, (2) Pallas and (4) Vesta. Astronomy & Astrophysics, 360, 363–374.Google Scholar

Millis, R. L., Wasserman, L. H., Franz, O. G., et al. (1987) The size, shape, density, and albedo of Ceres from its occultation of BD+8°471. Icarus, 72, 507–518.Google Scholar

Mitchell, D. L., Ostro, S. J., Hudson, R. S., et al. (1996) Radar observations of asteroids 1 Ceres, 2 Pallas, and 4 Vesta. Icarus, 124, 113–133.Google Scholar

Nathues, A., Hoffmann, M., Platz, T., et al. (2016) FC color images of dwarf planet Ceres reveal a complicated geological history. Planetary and Space Science, 134, 122–127.Google Scholar

Nathues, A., Platz, T., Hoffmann, M., et al. (2017a) Oxo crater on (1) Ceres: Geological history and the role of water-ice. Astronomical Journal, 154, 84–96.Google Scholar

Nathues, A., Platz, T., Thangjam, G., et al. (2017b) Evolution of Occator crater on (1) Ceres. Astronomical Journal, 153,112–123.Google Scholar

Nathues, A., Platz, T., Thangjam, G., et al. (2019) Occator crater in color at highest spatial resolution. Icarus, 320, 24–38.Google Scholar

Nathues, A., Schmedemann, N., Thangjam, G., et al. (2020) Recent cryovolcanic activity at Occator crater on Ceres. Nature Astronomy, 4, 794–801.Google Scholar

Neesemann, A., van Gesselt, S., Schmedemann, N., et al. (2019) The various ages of Occator crater, Ceres: Results of a comprehensive synthesis approach. Icarus, 320, 60–82.Google Scholar

Ostro, S. J., Pettengill, G. H., Shapiro, I. I., Campbell, D. B., & Green, R. R. (1979) Radar observations of asteroid 1 Ceres. Icarus, 40, 355–358.Google Scholar

Otto, K. A., Marchi, S., Trowbridge, A., Melosh, H. J., & Sizemore, H. G. (2019) Ceres crater degradation inferred from concentric fracturing. Journal of Geophysical Research: Planets, 124, 1188–1203.Google Scholar

Park, R. S., Vaughan, A. T., Konopliv, A. S., et al. (2019) High-resolution shape model of Ceres from stereophotoclinometry using Dawn imaging data. Icarus, 319, 812–827.Google Scholar

Pasckert, J. H., Hiesinger, H., Ruesch, O., et al. (2018) Geologic mapping of the Ac-2 Coniraya Quadrangle of Ceres from NASA’s Dawn Mission: Implications for a heterogeneously composed crust. Icarus, 316, 28–45.Google Scholar

Pitjeva, E. V., & Standish, E. M. (2009) Proposals for the masses of the three largest asteroids, the Moon–Earth mass ratio and the astronomical unit. Celestial Mechanics & Dynamical Astronomy, 103, 365–372.Google Scholar

Platz, T., Natheus, A., Sizemore, H. G., et al. (2018) Geological mapping of the Ac-10 Rongo Quadrangle of Ceres. Icarus, 316, 140–153.Google Scholar

Preusker, F., Scholten, F., Matz, K.-D., et al. (2016) Dawn at Ceres – Shape model and rotational state. 47th Lunar and Planetary Science Conference, March, Houston, TX, Abstract #1954.Google Scholar

Raponi, A., De Sanctis, M. C., Carrozzo, F. G., et al. (2019) Mineralogy of Occator crater on Ceres and insight into evolution from the properties carbonates, phyllosilicates, and chlorides. Icarus, 320, 83–96.Google Scholar

Raponi, A., De Sanctis, M. C., Frigeri, A., et al. (2018) Variations in the amount of water ice on Ceres’ surface suggest a seasonal water cycle. Science Advances, 4, eaao3757.Google Scholar

Raymond, C. A., Ermakov, A. I., Castillo-Rogez, J. C., et al. (2020) Impact-driven mobilization of deep crustal brines on dwarf planet Ceres. Nature Astronomy, 4, 741–747,Google Scholar

Rivkin, A. S., Li, J.-Y., Milliken, R. E., et al. (2011) The surface composition of Ceres. Space Science Reviews, 163, 95–116.Google Scholar

Ruesch, O., Platz, T., Schenk, P., et al. (2016) Cryovolcanism on Ceres. Science, Volume 353.Google Scholar

Ruesch, O., Quick, L., Landis, M. E., et al. (2019) Bright carbonate surfaces on Ceres as remnants of salt-rich water fountains. Icarus, 320, 39–48.Google Scholar

Ruiz, J., Jiménez-Díaz, A., Mansilla, F., et al. (2019) Evidence of thrust faulting and widespread contraction of Ceres. Nature Astronomy, 3, 916–921.Google Scholar

Russell, C. T., & Raymond, C. A. (2011) The Dawn mission to Vesta and Ceres. Space Science Reviews, 163, 3–23.Google Scholar

Russell, C. T., Raymond, C. A., Ammannito, C. A., et al. (2016) Dawn arrives at Ceres: Exploration of a small, volatile-rich world. Science, 353, 1008–1010.Google Scholar

Russell, C. T., Raymond, C. A., Coradini, A., et al. (2012) Dawn at Vesta: Testing the protoplanet paradigm. Science, 336, 684–686.Google Scholar

Schenk, P., O’Brien, D. P., Marchi, S., et al. (2012) The geologically recent giant impact basins at Vesta’s south pole. Science, 336, 694–697.Google Scholar

Schenk, P., Scully, J., Buczkowski, D., et al. (2020) Impact-driven brine-melt, volatile distribution, and brine effusion in crater floor deposits on a transitional ice-salt-silicate-rich dwarf planet at Occator crater, Ceres. Nature Commications, 11, 3679.Google Scholar

Schenk, P., Sizemore, H. G., Schmidt, B., et al. (2019) The central pit and dome at Cerealia Facula bright deposit and floor deposits in Occator crater, Ceres: Morphology, comparisons and formation. Icarus, 320, 159–187.Google Scholar

Schmedemann, N., Kneissl, T., Neesemann, A., et al. (2016) Timing of optical maturation of recently exposed material on Ceres. Geophysical Research Letters, 43, 11987–11993.Google Scholar

Schmidt, B. E., Hughson, K. H. G., Chilton, H. T., et al. (2017) Geomorphological evidence for ground ice on dwarf planet Ceres. Nature Geoscience, 10, 338–343.Google Scholar

Schmidt, B. E., Sizemore, H. G., Hughson, K. H. G., et al. (2020) Post-impact cryo-hydrologic formation of small mounds and hills in Ceres’ Occator crater. Nature Geoscience, 13, 605–610.Google Scholar

Schröder, S. E., Mottola, S., Carsenty, U., et al. (2017) Resolved spectrophotometric properties of the Ceres surface from Dawn Framing Camera images. Icarus, 288, 201–225.Google Scholar

Scully, J. E. C., Bowling, T., Bu, , C., et al. (2019a) Synthesis of the special issue: The formation and evolution of Occator crater. Icarus, 320, 213–225.Google Scholar

Scully, J. E. C., Buczkowski, D. L., Raymond, C. A., et al. (2019b) Ceres’ Occator crater and its faculae explored through geologic mapping. Icarus, 320, 7–23.Google Scholar

Scully, J. E. C., Schenk, P. M., Castillo-Rogez, J. C., et al. (2020) The varied sources of faculae-forming brines in Ceres’ Occator crater, emplaced via hydrothermal brine effusion. Nature Communications, 11, 3680.Google Scholar

Sierks, H., Keller, H. U., Jaumann, R., et al. (2011) The Dawn Framing Camera. Space Science Reviews, 163, 263–328.Google Scholar

Sizemore, H. G., Platz, T., Prettyman, T. H., et al. (2017) Pitted terrain on dwarf planet Ceres: Morphological evidence for shallow volatiles at low and mid latitudes. Geophysical Research Letters, 44, 6570–6578.Google Scholar

Sizemore, H. G., Schmidt, B. E., Buczkowski, D. A., et al. (2019) A global inventory of ice-related morphological features on dwarf planet Ceres: Implications for the evolution and current state of the cryosphere. Journal of Geophysical Research, 124, 1650–1689.Google Scholar

Sori, M. M., Byrne, S., Bland, M. T., et al. (2017) The vanishing cryovolcanoes of Ceres. Geophysical Research Letters, 44, 1243–1250,Google Scholar

Spencer, J. R., Lebofsky, L. A., & Sykes, M. V. (1989) Systematic biases in radiometric diameter determinations. Icarus, 78, 337–354.Google Scholar

Stein, N. T., Ehlmann, B. L., Palomba, E., et al. (2019) The formation and evolution of bright spots on Ceres. Icarus, 320, 188–201.Google Scholar

Stephan, K., Jaumann, R., Krohn, K., et al. (2017) An investigation of the bluish material on Ceres. Geophysical Research Letters, 44, 1660–1668.Google Scholar

Stephan, K., Jaumann, R., Wagner, R., et al. (2018) Dantu’s mineralogical properties – A view into the composition of Ceres’ crust. Meteoritics & Planetary Science, 53, 1866–1883.Google Scholar

Stephan, K., Jaumann, R., Zambon, F., et al. (2019) Ceres’ craters – relationships between surface composition and geology. Icarus, 318, 56–74.Google Scholar

Thomas, P. C., Binzel, R. P., Gaffey, M. J., et al. (1997a) Impact excavation on asteroid 4 Vesta: Hubble Space Telescope results. Science, 277, 1492–1495.Google Scholar

Thomas, P. C., Binzel, R. P., Gaffey, M. J., et al. (1997b) Vesta: Spin pole, size and shape from HST images, Icarus, 128, 88–94.Google Scholar

Thomas, P. C., Parker, J. W., McFadden, L. A., et al. (2005) Differentiation of the asteroid Ceres as revealed by its shape. Nature, 437, 224–226.Google Scholar

Tornabene, L., Osinski, G. R., McEwen, A. S., et al. (2012) Widespread crater-related pitted materials on Mars: Further evidence for the role of target volatiles during the impact process. Icarus, 220, 348–368.Google Scholar

Viateau, B., & Rapport, N. (2001) Mass and density of asteroids (4) Vesta and (11) Parthenope. Astronomy & Astrophysics, 370, 602–609.Google Scholar

Williams, D. A., Buczkowski, D. L., Mest, S. C., et al. (2018a) Introduction: The geological mapping of Ceres. Icarus, 316, 1–13.Google Scholar

Williams, D. A., Kneissl, T., Neesemann, A., et al. (2018b) The geology of the Kerwan quadrangle of dwarf planet Ceres: Investigating Ceres’ oldest impact basin. Icarus, 316, 99–113.Google Scholar

Zolotov, M. Y. (2009) On the composition and differentiation of Ceres. Icarus, 204, 183–193.Google Scholar

References

Alexander, C. M. O’D., Bowden, R., Fogel, M. L., & Howard, K. T. (2015) Carbonate abundances and isotopic compositions in chondrites. Meteoritics & Planetary Science, 50, 810–833.Google Scholar

Allen, D. E., & Seyfried, W. E. Jr. (2004) Serpentinization and heat generation: Constraints from Lost City and Rainbow hydrothermal systems. Geochimica et Cosmochimica Acta, 68, 1347–1354.Google Scholar

Anderson, J. D., Jacobson, R. A., McElrath, T. P., et al. (2001) Shape, mean radius, gravity field and interior structure of Callisto. Icarus, 153, 157–161.Google Scholar

Benedix, G. K., Leshin, L. A., Jackson, T., & Thiemens, M. H. (2003) Carbonates in CM2 chondrites: Constraints on alteration conditions from oxygen isotopic compositions and petrographic observations. Geochimica et Cosmochimica Acta, 67, 1577–1588.Google Scholar

Bland, P. A., Collins, G. S., Davison, T. M., et al. (2014) Pressure-temperature evolution of primordial Solar System solids during impact-induced compaction. Nature Communications, 5, 5451–5451.Google Scholar

Bland, P. A., Howard, L. E., Prior, D. J., et al. (2011) Earliest rock fabric formed in the Solar System preserved in a chondrule rim. Nature Geoscience, 4, 244–247.Google Scholar

Bland, P. A., Jackson, M. D., Coker, R. F., et al. (2009) Why aqueous alteration in asteroids was isochemical: High porosity ≠ high permeability. Earth and Planetary Science Letters, 287, 559–568.Google Scholar

Bland, P. A., & Travis, B. J. (2017) Giant convecting mud balls of the early Solar System. Science Advances, 3, e1602514.Google Scholar

Blum, J. (2004) Grain growth and coagulation. In Witt, A. N., Clayton, G. C., & Draine, B. T. (eds.), Astrophysics of Dust. San Francisco, CA: Astronomical Society of the Pacific, pp. 369–391.Google Scholar

Blum, J., & Schrapler, R. (2004) Structure and mechanical properties of high-porosity macroscopic agglomerates formed by random ballistic deposition. Physical Review Letters, 93: 115503-1–115503-4.Google Scholar

Bowling, T. J., Ciesla, F. J., Davison, T. M., et al. (2019) Post-impact thermal structure and cooling timescales of Occator crater on Asteroid 1 Ceres. Icarus, 320.Google Scholar

Brearley, A. J. (2003) Nebular versus parent body processing. in Davis, A. M. (ed.), Treatise on Geochemistry, Vol. 1. Amsterdam: Elsevier, pp. 247–268.Google Scholar

Brearley, A. J. (2006) The action of water. In Lauretta, D. S., & McSween, H. Y. Jr. (eds.), Meteorites and the Early Solar System II (pp. 587–624). Tucson: University of Arizona Press.Google Scholar

Carrozzo, F. G., De Sanctis, M. C., Raponi, A., et al. (2018) Nature, formation, and distribution of carbonates on Ceres. Science Advances, 4, e1701645.s.Google Scholar

Castillo-Rogez, J. C. (2011) Ceres – Neither a porous nor salty ball. Icarus, 215, 599–602.Google Scholar

Castillo-Rogez, J. C., Hesse, M., Formisano, M., et al. (2019) Conditions for the long‐term preservation of a deep brine Rreservoir in Ceres. Geophysical Research Letters, 46, 1963–1972.Google Scholar

Castillo-Rogez, J. C., & Lunine, J. I. (2010) Evolution of Titan’s rocky core constrained by Cassini observations. Geophysical Research Letters, 37, L20205.Google Scholar

Castillo-Rogez, J. C., & McCord, T. B. (2010) Ceres’ evolution and present state constrained by shape data. Icarus, 205, 443–459.Google Scholar

Castillo-Rogez, J. C., Neveu, M., McSween, H. Y., et al. (2018) Insights into Ceres’ evolution from surface composition. Meteoritics & Planetary Science, 53, 1820–1843.Google Scholar

Castillo-Rogez, J. C., Neveu, M., Scully, J. E. C., et al. (2020) Ceres: Astrobiological target and possible ocean world. Astrobiology, 20, 269–291.Google Scholar

Castillo-Rogez, J. C., & Schmidt, B. E. (2010) Geophysical evolution of the Themis family parent body. Geophysical Research Letters, 37, L10202.Google Scholar

Castillo-Rogez, J. C., & Young, E. D. (2016) Origin and evolution of volatile-rich planetesimals. In Elkins-Tanton, L., & Weiss, B. (eds.), Planetesimal Differentiation. Cambridge: Cambridge University Press, pp. 92–114.Google Scholar

Chan, Q. H. S., Zolensky, M. E., Kebukawa, Y., et al. (2018) Organic matter in extraterrestrial water-bearing salt crystals. Science Advances, 4, eaao3521.Google Scholar

Choblet, G., Tobie, G., Sotin, C., et al. (2017) Powering prolonged hydrothermal activity inside Enceladus. Nature Astronomy, 1, 841–847.Google Scholar

Choukroun, M., Kieffer, S., Lu, X., & Tobie, G. (2013) Clathrate hydrates: Implication for exchange processes in the outer Solar System. In Gudipati, S. M., & Castillo-Rogez, J. C. (eds.), Science of Solar System Ices, 3rd ed. (Astrophysics and Space Science Library, 356, pp. 409–454). New York: Springer.Google Scholar

Clauser, C., & Huenges, E. (1995) Thermal conductivity of rocks and minerals. In Ahrens, T. J. (ed.), Rock Physics & Phase Relations. Washington, DC: American Geophysical Union.Google Scholar

Clayton, R. N., & Mayeda, T. K. (1999) Oxygen isotope studies of carbonaceous chondrites. Geochimica et Cosmochimica Acta, 63, 2089–2104.Google Scholar

De Sanctis, M. C., Ammanito, E., Raponi, E., et al. (2015) Ammoniated phyllosilicates with a likely outer Solar System origin on (1) Ceres. Nature, 528, 241–244.Google Scholar

De Sanctis, M. C., Ammannito, E., Raponi, A., et al. (2020) Recent emplacement of hydrated sodium chloride on Ceres from ascending salty fluids. Nature Astronomy, 4, 786–793.Google Scholar

Desch, S. J., Kalyaan, A., & Alexender, C. M. O’D. (2018) The effect of Jupiter’s formation on the distribution of refractory elements and inclusions in meteorites. The Astrophysical Journal Supplement Series, 238, 11.Google Scholar

Dullien, F. A. L. (1992) Porous Media, Fluid Transport and Pore Structure, 2nd ed. Cambridge, MA: Academic Press.Google Scholar

Durham, W. B., Prieto-Ballesteros, O., Goldsby, D. L., & Kargel, J. S. (2010) Rheological and thermal properties of icy materials. Space Science Reviews, 153, 273–298.Google Scholar

Dyl, K. A., Manning, C. E., & Young, E. D. (2010) The implications of cronstedtite formation in water-rich planetesimals and asteroids. Astrobiology Science Conference 2010: Evolution and Life: Surviving Catastrophes and Extremes on Earth and Beyond, April 2010, League City, TX. LPI Contrib. 1538, #5627.Google Scholar

El-Dessouky, H. T., & Ettouney, H. M. (2002) Fundamentals of Salt Water Desalination. Amsterdam: Elsevier Science B.V.Google Scholar

Formisano, M., Federico, C., Castillo-Rogez, J., De Sanctis, M. C., & Magni, G. (2020) Thermal convection in the crust of the dwarf planet Ceres. Monthly Notices of the Royal Astronomical Society, 494, 5704–5712.Google Scholar

Fu, R., Ermakov, E., Marchi, S., et al. (2017) Interior structure of the dwarf planet Ceres as revealed by surface topography. Earth and Planetary Science Letters, 476, 153–164.Google Scholar

Fujiya, W., Sugiura, N., Marrocchi, Y., et al. (2015) Comprehensive study of carbon and oxygen isotopic compositions, trace element abundances, and cathodoluminescence intensities of calcite in the Murchison CM chondrite. Geochimica et Cosmochimica Acta, 70, 101–117.Google Scholar

Gao, P., & Stevenson, D. J. (2013) Nonhydrostatic effects and the determination of icy satellites’ moment of inertia. Icarus, 226, 1185–1191.Google Scholar

Glein, C. R., Desch, S. J., & Shock, E. L. (2009) The absence of endogenic methane on Titan and its implications for the origin of atmospheric nitrogen. Icarus, 204, 637–644.Google Scholar

Gounelle, M., & Zolensky, M. E. (2001) A terrestrial origin for sulfate veins in CI1 chondrites. Meteoritics & Planetary Science, 36, 1321–1329.Google Scholar

Guo, W., & Eiler, J. M. (2007) Temperatures of aqueous alteration and evidence for methane generation on the parent bodies of the CM chondrites. Geochimica et Cosmochimica Acta, 71, 5565–5575.Google Scholar

Hendrix, A. R., Hurford, T. A., Barge, L. M., et al. (2019) The NASA roadmap to ocean worlds. Astrobiology, 19.Google Scholar

Howard, K. T., Benedix, G. K., Bland, P. A., & Cressey, G. (2009) Modal mineralogy of CM2 chondrites by X-ray diffraction (PSD-XRD). Part 1: Total phyllosilicate abundance and the degree of aqueous alteration. Geochimica et Cosmochimica Acta, 73, 4576–4589.Google Scholar

Hsieh, H. H. (2012) Main-belt comets as tracers of ice in the inner Solar System. Proceedings of the International Astronomical Union 8, Issue S293 (Formation, Detection, and Characterization of Extrasolar Habitable Planets), 212–218.Google Scholar

Hussmann, H., Sohl, F., & Spohn, T. (2006) Subsurface oceans and deep interiors of medium-sized outer planet satellites and large trans-Neptunian objects. Icarus, 185, 258–273.Google Scholar

Iess, L., Stevenson, D. J., Parisi, M., et al. (2014) The gravity field and interior structure of Enceladus. Science, 344, 78–80.Google Scholar

Jogo, K., Nakamura, T., Ito, M., et al. (2017) Mn-Cr ages and formation conditions of fayalite in CV3 carbonaceous chondrites: Constraints on the accretion ages of chondritic asteroids. Geochimica et Cosmochimica Acta, 199, 58–74.Google Scholar

Kamata, S., Nimmo, F., Sekine, Y., et al. (2019) Pluto’s ocean is capped and insulated by gas hydrates. Nature Geoscience, 12, 407–410.Google Scholar

Keil, K. (2000) Thermal alteration of asteroids: Evidence from meteorites. Planetary and Space Science, 48, 887–903.Google Scholar

King, S. D., Castillo-Rogez, J. C., Toplis, M. J., et al. (2018) Ceres internal structure from geophysical constraints. Meteoritics & Planetary Science, 53, 1999–2007.Google Scholar

Kivelson, M. G., Khurana, K. K., & Volwerk, M. (2002) The permanent and inductive magnetic moments of Ganymede. Icarus, 157, 507–522.Google Scholar

Kranck, K. (1973) Flocculation of suspended sediment in the sea. Nature, 246, 348–350.Google Scholar

Lee, M. R., Lindgren, P., & Sofe, M. R. (2014) Aragonite, breunnerite, calcite and dolomite in the CM carbonaceous chondrites: High fidelity recorders of progressive parent body aqueous alteration. Geochimica et Cosmochimica Acta, 144, 126–156.Google Scholar

Leshin, L. A., Rubin, A. E., & McKeegan, K. D. (1997) The oxygen isotopic composition of olivine and pyroxene from CI chondrites. Geochimica et Cosmochimica Acta, 61, 835–845.Google Scholar

Lodders, K., Palme, H., & Gail, H. P. (2009) Abundances of elements in the Solar System, in Trumper, J. E. (ed.), Landolt-Bornstein, New Series, Astronomy and Astrophysics. Berlin: Springer Verlag.Google Scholar

Macke, R. J., Consolmagno, G. J., & Britt, D. T. (2011) Density, porosity, and magnetic susceptibility of carbonaceous chondrites. Meteoritics & Planetary Science, 46, 1842–1862.Google Scholar

Maiorca, E., Uitenbroek, H., Uttenthaler, S., et al. (2014) A new solar fluorine abundance and a fluorine determination in the two open clusters M67 and NGC 6404. The Astrophysical Journal, 788, 149.Google Scholar

Mao, X., & McKinnon, W. B. (2018) Faster paleospin and deep-seated uncompensated mass as possible explanations for Ceres’ present-day shape and gravity. Icarus, 299, 430–442.Google Scholar

Marchi, S., Ermakov, A. I., Raymond, C. A., et al. (2016) The missing large impact craters on Ceres. Nature Communications, 7, 12257.Google Scholar

Marchi, S., Raponi, A., Prettyman, T. H., et al. (2019) An aqueously altered carbon-rich Ceres. Nature Astronomy, 3, 140–145.Google Scholar

Marsset, M., Brož, M., Vernazza, P., et al. (2020) The violent collisional history of aqueously evolved (2) Pallas. Nature Astronomy, 4, 569–576.Google Scholar

Marsset, M., Vernazza, P., Birlan, M., et al. (2016) Compositional characterization of the Themis family. Astronomy & Astrophysics, 586, id.A15.Google Scholar

Marzari, F., Davis, D., & Vanzani, V. (1995) Collisional evolution of asteroid families. Icarus, 113, 168–187.Google Scholar

McCord, T. B., & Sotin, C. (2005) Ceres: Evolution and current state. Journal of Geophysical Research, 110, EO5009–EO5014.Google Scholar

McKinnon, W. B., & Zolensky, M. E. (2003) Sulfate content of Europa’s ocean and shell: Evolutionary considerations and some geological and astrobiological implications. Astrobiology, 3, 879–897.Google Scholar

McSween, H. Y., Emery, J. P., Rivkin, A. S., et al. (2018) Carbonaceous chondrite analogs for the composition and alteration of Ceres. Meteoritics & Planetary Science, 53, 1793–1804.Google Scholar

Mueller, S., & McKinnon, W. B. (1989) Three-layered models of Ganymede and Callisto: Compositions, structures, and aspects of evolution. Icarus, 76, 437–464.Google Scholar

Néri, A., Guyot, F., Reynard, B., & Sotin, C. (2019) A carbonaceous chondrite and cometary origin for icy moons of Jupiter and Saturn. Earth and Planetary Science Letters, 530, id. 115920.Google Scholar

Neumann, W., Jaumann, R., Castillo-Rogez, J. C., Raymond, C. A., & Russell, C. T. (2020) Ceres’ partial differentiation: Undifferentiated crust mixing with a water-rich mantle. Astronomy and Astrophysics, 633, A117.Google Scholar

Neveu, M., & Desch, S. J. (2015) Geochemistry, thermal evolution, and cryovolcanism on Ceres with a muddy mantle. Geophysical Research Letters, 42, 10,197–10,206.Google Scholar

Neveu, M., Desch, S.J., & Castillo-Rogez, J. C. (2015) Core cracking and hydrothermal circulation can profoundly affect Ceres’ geophysical evolution. Journal of Geophysical Research, 120, 123–154.Google Scholar

Neveu, M., Desch, S. J., & Castillo-Rogez, J. C. (2017) Aqueous geochemistry in icy world interiors: Fate of antifreezes and radionuclides. Cosmochimica et Geochimica Acta, 212, 324–371.Google Scholar

Neveu, M., & Vernazza, P. (2019) IDP-like asteroids formed later than 5 Myr after Ca-Al-rich inclusions. The Astrophysical Journal, 875, id. 30.Google Scholar

Ormel, C. W., Cuzzi, J. N., & Tielens, A. G. G. M. (2008) Co-accretion of chondrules and dust in the solar nebula. The Astrophysical Journal, 679, 1588–1610.Google Scholar

Palomba, E., Longobardo, A., De Sanctis, M. C., et al. (2019) Compositional differences among Bright Spots on the Ceres surface. Icarus, 320, 202–212.Google Scholar

Park, R. S., Konopliv, A. S., Ermakov, A. I., et al. (2020) Evidence of non-uniform crust of Ceres from Dawn’s high-resolution gravity data. Nature Astronomy, 4, 748–755.Google Scholar

Postberg, F., Schmidt, J., Hillier, J., Kempf, S., & Srama, R. (2011) A salt-water reservoir as a source of compositionally stratified plume on Enceladus. Nature, 474, 620–622.Google Scholar

Prettyman, T. H., Yamashita, N., Ammannito, E., et al. (2018) Elemental composition and mineralogy of Vesta and Ceres: Distribution and origins of hydrogen-bearing species. Icarus, 318, 42–55.Google Scholar

Prettyman, T. H., Yamashita, N., Toplis, M. J., et al. (2017) Extensive water ice within Ceres’ aqueously altered regolith: Evidence from nuclear spectroscopy. Science, 355, 55–59.Google Scholar

Raponi, M. C., De Sanctis, F. G., Carrozzo, M., et al. (2019) Mineralogy of Occator crater on Ceres and insight into its evolution from the properties of carbonates, phyllosilicates, and chlorides. Icarus, 320, 83–96.Google Scholar

Raymond, C. A., Castillo-Rogez, I., Ermakov, S., et al. (2020) Impact-driven mobilization of deep crustal brines on dwarf planet Ceres. Nature Astronomy, 4, 741–747.Google Scholar

Rivkin, A. S., & Emery, J. P. (2010) Detection of ice and organics on an asteroidal surface. Nature, 464, 1322–1323.Google Scholar

Rivkin, A. S., Howell, E. S., & Emery, J. P. (2019) Infrared spectroscopy of large, low-albedo asteroids: Are Ceres and Themis archetypes or outliers? Journal of Geophysical Research, 124, 1393–1409.Google Scholar

Roberts, J. H. (2015) The flully core of Enceladus. Icarus, 258, 54–66.Google Scholar

Rubin, A. E., Zolensky, M. E., & Bodnar, R. J. (2002) The halite‐bearing Zag and Monahans (1998) meteorite breccias: Shock metamorphism, thermal metamorphism and aqueous alteration on the H‐chondrite parent body. Meteoritics & Planetary Science, 37, 125–141.Google Scholar

Ruesch, O., Genova, A., Neumann, W., et al. (2019) Slurry extrusion on Ceres from a convective mud-bearing mantle. Nature Geoscience, 12, 505–509.Google Scholar

Ruesch, O., Platz, T., Schenk, P., et al. (2016) Cryovolcanism on Ceres. Science, 353, aaf4286.Google Scholar

Santibanez, P. A., Michaud, A. B., Vick-Majors, T. J., et al. (2019) Differential incorporation of bacteria, organic matter, and inorganic ions into lake ice during ice formation. Journal of Geophysical Research – Biogeosciences, 124, 585–600.Google Scholar

Sasso, M. R., Macke, R. J., Boesenberg, J. S., et al. (2009) Incompletely compacted equilibrated ordinary chondrites. Meteoritics & Planetary Science, 44, 1743–1753.Google Scholar

Schenk, P. M. (2002) Thickness constraints on the icy shells of the galilean satellites from a comparison of crater shapes. Nature, 417, 419–421.Google Scholar

Schrader, D. L., Franchi, I. A., Connolly, H. C. Jr., et al. (2011) The formation and alteration of the Renazzo-like carbonaceous chondrites I: Implications of bulk-oxygen isotopic composition. Geochimica et Cosmochimica Acta, 75, 308–325.Google Scholar

Scott, H. P., Williams, Q., & Ryerson, F. J. (2002) Experimental constraints on the chemical evolution of icy satellites. Earth and Planetary Science Letters, 203, 399–412.Google Scholar

Scully, J. E. C., Schenk, P. M., Buczkowski, D. L., et al. (2020) Formation of the bright faculae in Ceres’ Occator crater via long-lived brine effusion in a hydrothermal system. Nature Communications, 11, 3680.Google Scholar

Sheppard, S. S., & Trujillo, C. (2015) Discovery and characteristics of the rapidly rotating active asteroid (62412) 2000 SY178 in the Main Belt. Astronomy Journal, 149, id. 44.Google Scholar

Sirono, S.-I. (2013) Differentiation of silicates from H2O ice in an icy body induced by ripening. Earth, Planets and Space, 65, 1563–1568.Google Scholar

Sizemore, H. G., Schmidt, B. E., Buczkowski, D. A., et al. (2019) A global inventory of ice‐related morphological features on dwarf planet Ceres: Implications for the evolution and current state of the cryosphere. Journal of Geophysical Research, 124, 1650–1689.Google Scholar

Sleep, N. H., Meibom, A., Fridriksson, Th., Coleman, R. G., & Bird, D. K. (2004) H2-rich fluids from serpentinization: Geochemical and biotic implications. Proceedings of the National Academy of Sciences (USA), 101, 12818–12823.Google Scholar

Stein, N. T., Ehlmann, B. L., Bland, M., Castillo-Rogez, J., & Stevenson, D. (2019) The formation and timing of near-surface Na-carbonate deposits on Ceres. Europlanet Science Congress, 13, EPSC-DPS2019–1194-1.Google Scholar

Stein, N. T., Ehlmann, B. L., Palomba, E., et al. (2017) The formation and evolution of bright spots on Ceres, Icarus, 320, 188–201.Google Scholar

Tosi, F., Carrozzo, F. G., Raponi, A., et al. (2018) Mineralogy and temperature of crater Haulani on Ceres. Meteoritics & Planetary Science, 53, 1902–1924.Google Scholar

Travis, B. J., Bland, P. A., Feldman, W. C., & Sykes, M. (2018) Hydrothermal dynamics in a CM-based model of Ceres. Meteoritics & Planetary Science, 53, 2008–2032.Google Scholar

Travis, B. J., & Schubert, G. (2015) Keeping Enceladus warm. Icarus, 250, 32–42.Google Scholar

Vance, S. E., Harnmeijer, J., Kimura, J., et al. (2007) Hydrothermal systems in small ocean planets. Astrobiology, 7, 987–1005.Google Scholar

Vance, S. E., & Melwani Daswani, M. (2020) Serpentinite and the search for life beyond Earth. Philosophical Transactions of the Royal Society A, 378, 20180421.Google Scholar

Vernazza, P., Brož, M., Drouard, A., et al. (2018) The impact crater at the origin of the Julia family detected with VLT/SPHERE? Astronomy & Astrophysics, 618, id.A154.Google Scholar

Vernazza, P., Castillo-Rogez, J., Beck, P., et al. (2017) Different origins or different evolutions? Decoding the spectral diversity among C-type asteroids. The Astronomical Journal, 153, 72.Google Scholar

Vernazza, P., Jorda, L., Ševeček, P., et al. (2019) A basin-free spherical shape as an outcome of a giant impact on asteroid Hygiea. Nature Astronomy, 4, 136–141.Google Scholar

Young, E. D., Ash, R. D., England, P. & Rumble, D. (1999) Fluid flow in chondritic parent bodies: Deciphering the composition of planetesimals. Science, 286, 1331–1335.Google Scholar

Young, E. D., Zhang, K. K., & Schubert, G. (2003) Conditions for water pore convection within carbonaceous chondrite parent bodies – Implications for planetesimal size and heat production. Earth and Planetary Science Letters, 213, 249–259.Google Scholar

Zambon, F., Raponi, A., Tosi, F., et al. (2017) Spectral analysis of Ahuna Mons mission’s visible-infrared spectrometer. Geophysical Research Letters, 44, 97–104.Google Scholar

Ziffer, J., Campins, H., Licandro, J., et al. (2011) Near-infrared spectroscopy of primitive asteroid families. Icarus, 213, 538–546.Google Scholar

Zimmer, C., Khurana, K. K., & Kivelson, M. G. (2000) Subsurface oceans on Europa and Callisto: Constraints from Galileo magnetometer observations. Icarus, 147, 329–347.Google Scholar

Zolensky, M. E., Bourcier, W. L., & Gooding, J. L. (1989) Aqueous alteration on the hydrous asteroids – Results of EQ3/6 computer simulations. Icarus, 78, 411–425.Google Scholar

Zolotov, M. Y. (2014) Formation of brucite and cronstedtite-bearing mineral assemblages on Ceres. Icarus, 228, 13–26.Google Scholar

Zolotov, M. Y. (2020) The composition and structure of Ceres’ interior. Icarus, 335, 113404.Google Scholar

Zolotov, M. Y., & Shock, E. L. (2001) Composition and stability of salts on the surface of Europa and their oceanic origin. Journal of Geophysical Research, 106, 32815–32827.Google Scholar

References

Ammannito, E., De Sanctis, M. C., Palomba, E., et al. (2013) Olivine in an unexpected location on Vesta’s surface. Nature, 504, 122–125.Google Scholar

Bangerth, W., Hartmann, R., & Kanschat, G. (2007) Deal. II – a general-purpose object-oriented finite element library. ACM Transactions on Mathematical Software (TOMS), 33, 24-es.Google Scholar

Barrat, J. A., Yamaguchi, A., Zanda, B., Bollinger, C., & Bohn, M. (2010) Relative chronology of crust formation on asteroid Vesta: Insights from the geochemistry of diogenites. Geochimica et Cosmochimica Acta, 74, 6218–6231.Google Scholar

Beck, A. W., & McSween, H. Y. Jr (2010) Diogenites as polymict breccias composed of orthopyroxenite and harzburgite. Meteoritics & Planetary Science, 45, 850–872.Google Scholar

Beuthe, M., Rivoldini, A., & Trinh, A. (2016) Enceladus’s and Dione’s floating ice shells supported by minimum stress isostasy. Geophysical Research Letters, 43, 10088.Google Scholar

Bills, B. G., & Ermakov, A. I. (2019) Simple models of error spectra for planetary gravitational potentials as obtained from a variety of measurement configurations. Planetary and Space Science, 179, 104744.Google Scholar

Bills, B. G., & Scott, B. R. (2017) Secular obliquity variations of Ceres and Pallas. Icarus, 284, 59–69.Google Scholar

Bills, B. G., Asmar, S. W., Konopliv, A. S., Park, R. S., & Raymond, C. A. (2014) Harmonic and statistical analyses of the gravity and topography of Vesta. Icarus, 240, 161–173.Google Scholar

Bland, M. T. (2013) Predicted crater morphologies on Ceres: Probing internal structure and evolution. Icarus, 226, 510–521.Google Scholar

Bland, M. T., Ermakov, A. I., Raymond, C. A., et al. (2018) Morphological indicators of a mascon beneath Ceres’s largest crater, Kerwan. Geophysical Research Letters, 45, 1297–1304.Google Scholar

Bland, M. T., Raymond, C. A., Schenk, P. M., et al. (2016) Composition and structure of the shallow subsurface of Ceres revealed by crater morphology. Nature Geoscience, 9, 538–542.Google Scholar

Buczkowski, D. L., Wyrick, D. Y., Toplis, M., et al. (2014) The unique geomorphology and physical properties of the Vestalia Terra plateau. Icarus, 244, 89–103.Google Scholar

Čadek, O., Souček, O., & Běhounková, M. (2019) Is Airy isostasy applicable to icy moons? Geophysical Research Letters, 46, 14299–14306.Google Scholar

Carry, B., Dumas, C., Fulchignoni, M., et al. (2008) Near-infrared mapping and physical properties of the dwarf-planet Ceres. Astronomy & Astrophysics, 478, 235–244.Google Scholar

Castillo-Rogez, J. C., Matson, D. L., Sotin, C., et al. (2007) Iapetus’ geophysics: Rotation rate, shape, and equatorial ridge. Icarus, 190, 179–202.Google Scholar

Castillo-Rogez, J. C., & McCord, T. B. (2010) Ceres’ evolution and present state constrained by shape data. Icarus, 205, 443–459.Google Scholar

Castillo‐Rogez, J., Neveu, M., McSween, H. Y., et al. (2018) Insights into Ceres’s evolution from surface composition. Meteoritics & Planetary Science, 53, 1820–1843.Google Scholar

Chamberlain, M. A., Sykes, M. V., & Esquerdo, G. A. (2007) Ceres lightcurve analysis – Period determination. Icarus, 188, 451–456.Google Scholar

Clenet, H., Jutzi, M., Barrat, J. A., et al. (2014) A deep crust–mantle boundary in the asteroid 4 Vesta. Nature, 511, 303–306.Google Scholar

Consolmagno, G. J., Golabek, G. J., Turrini, D., et al. (2015) Is Vesta an intact and pristine protoplanet? Icarus, 254, 190–201.Google Scholar

De Sanctis, M. C., Ammannito, E., Raponi, A., et al. (2020) Fresh emplacement of hydrated sodium chloride on Ceres from ascending salty fluids. Nature Astronomy, 4, 786–793.Google Scholar

Dermott, S. F. (1979) Shapes and gravitational moments of satellites and asteroids. Icarus, 37, 575–586.Google Scholar

Dobrovolskis, A. R., & Burns, J. A. (1984) Angular momentum drain: A mechanism for despinning asteroids. Icarus, 57, 464–476.Google Scholar

Dobson, D. P., Crichton, W. A., Vocadlo, L., et al. (2000) In situ measurement of viscosity of liquids in the Fe–FeS system at high pressures and temperatures. American Mineralogist, 85, 1838–1842.Google Scholar

Durante, D., Hemingway, D. J., Racioppa, P., Iess, L., & Stevenson, D. J. (2019) Titan’s gravity field and interior structure after Cassini. Icarus, 326, 123–132.Google Scholar

Ermakov, A. I. (2017) Geophysical Investigation of Vesta, Ceres and the Moon Using Gravity and Topography Data. Doctoral dissertation, Massachusetts Institute of Technology.Google Scholar

Ermakov, A. I., Fu, R. R., Castillo‐Rogez, J. C., et al. (2017a) Constraints on Ceres’ internal structure and evolution from its shape and gravity measured by the Dawn spacecraft. Journal of Geophysical Research: Planets, 122, 2267–2293.Google Scholar

Ermakov, A. I., Mazarico, E., Schröder, S. E., et al. (2017b) Ceres’s obliquity history and its implications for the permanently shadowed regions. Geophysical Research Letters, 44, 2652–2661.Google Scholar

Ermakov, A. I., Zuber, M. T., Smith, D. E., et al. (2014) Constraints on Vesta’s interior structure using gravity and shape models from the Dawn mission. Icarus, 240, 146–160.Google Scholar

Formisano, M., Federico, C., Turrini, D., et al. (2013) The heating history of Vesta and the onset of differentiation. Meteoritics & Planetary Science, 48, 2316–2332.Google Scholar

Freed, A. M., Johnson, B. C., Blair, D. M., et al. (2014). The formation of lunar mascon basins from impact to contemporary form. Journal of Geophysical Research: Planets, 119, 2378–2397.Google Scholar

Fu, R. R., Ermakov, A. I., Marchi, S., et al. (2017) The interior structure of Ceres as revealed by surface topography. Earth and Planetary Science Letters, 476, 153–164.Google Scholar

Fu, R. R., Hager, B. H., Ermakov, A. I., & Zuber, M. T. (2014) Efficient early global relaxation of asteroid Vesta. Icarus, 240, 133–145.Google Scholar

Fu, R. R., Weiss, B. P., Shuster, D. L., et al. (2012) An ancient core dynamo in asteroid Vesta. Science, 338, 238–241.Google Scholar

Gaskell, R. W. (2012) SPC shape and topography of Vesta from DAWN imaging data. AAS/Division for Planetary Sciences Meeting Abstracts, # 44 (Vol. 44), October, Reno, NV.Google Scholar

Ghosh, A., & McSween, H. Y. Jr (1998) A thermal model for the differentiation of asteroid 4 Vesta, based on radiogenic heating. Icarus, 134, 187–206.Google Scholar

Hemingway, D., Nimmo, F., Zebker, H., & Iess, L. (2013) A rigid and weathered ice shell on Titan. Nature, 500, 550–552.Google Scholar

Hesse, M. A., & Castillo‐Rogez, J. C. (2019) Thermal evolution of the impact‐induced cryomagma chamber beneath Occator crater on Ceres. Geophysical Research Letters, 46, 1213–1221.Google Scholar

Hiesinger, H., Marchi, S., Schmedemann, N., et al. (2016) Cratering on Ceres: Implications for its crust and evolution. Science, 353, aaf4759.Google Scholar

Hirth, G., & Kohlstedt, D. L. (1996) Water in the oceanic upper mantle: Implications for rheology, melt extraction and the evolution of the lithosphere. Earth and Planetary Science Letters, 144, 93–108.Google Scholar

Hughson, K. H., Russell, C. T., Schmidt, B. E., et al. (2019) Normal faults on Ceres: Insights into the mechanical properties and thermal history of Nar Sulcus. Geophysical Research Letters, 46, 80–88.Google Scholar

Ivanov, B. A., & Melosh, H. J. (2013) Two‐dimensional numerical modeling of the Rheasilvia impact formation. Journal of Geophysical Research: Planets, 118, 1545–1557.Google Scholar

Jaumann, R., Williams, D. A., Buczkowski, D. L., et al. (2012) Vesta’s shape and morphology. Science, 336, 687–690.Google Scholar

Johnson, T. V., & McGetchin, T. R. (1973) Topography on satellite surfaces and the shape of asteroids. Icarus, 18, 612–620.Google Scholar

Jutzi, M., & Asphaug, E. (2011) Mega‐ejecta on asteroid Vesta. Geophysical Research Letters, 38, 1–5.Google Scholar

Jutzi, M., Asphaug, E., Gillet, P., Barrat, J. A., & Benz, W. (2013) The structure of the asteroid 4 Vesta as revealed by models of planet-scale collisions. Nature, 494, 207–210.Google Scholar

Keane, J. T., & Ermakov, A. I. (2019) No evidence for true polar wander of Ceres. Nature Geoscience, 12, 972–974.Google Scholar

King, S. D., Castillo‐Rogez, J. C., Toplis, M. J., et al. (2018) Ceres internal structure from geophysical constraints. Meteoritics & Planetary Science, 53, 1999–2007.Google Scholar

Konopliv, A. S., Asmar, S. W., Bills, B. G., et al. (2011a) The Dawn gravity investigation at Vesta and Ceres. Space Science Reviews, 163, 461–486.Google Scholar

Konopliv, A. S., Asmar, S. W., Folkner, W. M., et al. (2011b) Mars high resolution gravity fields from MRO, Mars seasonal gravity, and other dynamical parameters. Icarus, 211, 401–428.Google Scholar

Konopliv, A. S., Asmar, S. W., Park, R. S., et al. (2014) The Vesta gravity field, spin pole and rotation period, landmark positions, and ephemeris from the Dawn tracking and optical data. Icarus, 240, 103–117.Google Scholar

Konopliv, A. S., Park, R. S., & Ermakov, A. I. (2020) The Mercury gravity field, orientation, love number, and ephemeris from the MESSENGER radiometric tracking data. Icarus, 335, 113386.Google Scholar

Konopliv, A. S., Park, R. S., Vaughan, A. T., et al. (2018) The Ceres gravity field, spin pole, rotation period and orbit from the Dawn radiometric tracking and optical data. Icarus, 299, 411–429.Google Scholar

Kovačević, A., & Kuzmanoski, M. (2007) A new determination of the mass of (1) Ceres. Earth, Moon, and Planets, 100, 117–123.Google Scholar

Lebofsky, L. A. (1978) Asteroid 1 Ceres: Evidence for water of hydration. Monthly Notices of the Royal Astronomical Society, 182, 17P–21P.Google Scholar

Lebofsky, L. A., Feierberg, M. A., Tokunaga, A. T., Larson, H. P., & Johnson, J. R. (1981) The 1.7-to 4.2-μm spectrum of asteroid 1 Ceres: Evidence for structural water in clay minerals. Icarus, 48, 453–459.Google Scholar

Li, S., & Milliken, R. E. (2015) Estimating the modal mineralogy of eucrite and diogenite meteorites using visible–near infrared reflectance spectroscopy. Meteoritics & Planetary Science, 50, 1821–1850.Google Scholar

Lichtenberg, T., Golabek, G. J., Gerya, T. V., & Meyer, M. R. (2016). The effects of short-lived radionuclides and porosity on the early thermo-mechanical evolution of planetesimals. Icarus, 274, 350–365.Google Scholar

Mandler, B. E., & Elkins‐Tanton, L. T. (2013) The origin of eucrites, diogenites, and olivine diogenites: Magma ocean crystallization and shallow magma chamber processes on Vesta. Meteoritics & Planetary Science, 48, 2333–2349.Google Scholar

Mao, X., & McKinnon, W. B. (2018a) Effect of impacts on Ceres’ spin evolution. Lunar and Planetary Science Conference (Vol. 49). The Woodlands, TX.Google Scholar

Mao, X., & McKinnon, W. B. (2018b) Faster paleospin and deep-seated uncompensated mass as possible explanations for Ceres’ present-day shape and gravity. Icarus, 299, 430–442.Google Scholar

Marchi, S., Ermakov, A. I., Raymond, C. A., et al. (2016) The missing large impact craters on Ceres. Nature Communications, 7, 12257.Google Scholar

Marchi, S., Raponi, A., Prettyman, T. H., et al. (2019) An aqueously altered carbon-rich Ceres. Nature Astronomy, 3, 140–145.Google Scholar

McCord, T. B., Adams, J. B., & Johnson, T. V. (1970) Asteroid Vesta: Spectral reflectivity and compositional implications. Science, 168, 1445–1447.Google Scholar

McCord, T. B., & Sotin, C. (2005) Ceres: Evolution and current state. Journal of Geophysical Research: Planets, 110, 1–14.Google Scholar

McSweenJr, H. Y., Binzel, R. P., De Sanctis, M. C., et al. (2013) Dawn; the Vesta–HED connection; and the geologic context for eucrites, diogenites, and howardites. Meteoritics & Planetary Science, 48, 2090–2104.Google Scholar

Melosh, H. J. (2011) Planetary Surface Processes. Cambridge: Cambridge University Press.Google Scholar

Melosh, H. J., Freed, A. M., Johnson, B. C., et al. (2013) The origin of lunar mascon basins. Science, 340, 1552–1555.Google Scholar

Milliken, R. E., & Rivkin, A. S. (2009) Brucite and carbonate assemblages from altered olivine-rich materials on Ceres. Nature Geoscience, 2, 258–261.Google Scholar

Moore, W. B., & Webb, A. A. G. (2013) Heat-pipe earth. Nature, 501, 501–505.Google Scholar

Morbidelli, A., & Nesvorny, D. (2019) Kuiper belt: formation and evolution. In Prialnik, D., Barucci, M. A., & Young, L. (eds.), The Trans-Neptunian Solar System. Amsterdam: Elsevier, p. 25.Google Scholar

Muller, P. M., & Sjogren, W. L. (1968) Mascons: Lunar mass concentrations. Science, 161, 680–684.Google Scholar

Nathues, A., Schmedemann, N., Thangjam, G., et al. (2020) Recent cryovolcanic activity at Occator crater on Ceres. Nature Astronomy, 4, 794–801.Google Scholar

Nesvorný, D., Li, R., Youdin, A. N., Simon, J. B., & Grundy, W. M. (2019) Trans-Neptunian binaries as evidence for planetesimal formation by the streaming instability. Nature Astronomy, 3, 808–812.Google Scholar

Neumann, G. A., Zuber, M. T., Smith, D. E., & Lemoine, F. G. (1996) The lunar crust: Global structure and signature of major basins. Journal of Geophysical Research: Planets, 101, 16841–16863.Google Scholar

Neumann, G. A., Zuber, M. T., Wieczorek, M. A., et al. (2004) Crustal structure of Mars from gravity and topography. Journal of Geophysical Research: Planets, 109, 1–18.Google Scholar

Neumann, W., Breuer, D., & Spohn, T. (2014) Differentiation of Vesta: Implications for a shallow magma ocean. Earth and Planetary Science Letters, 395, 267–280.Google Scholar

Neumann, W., Jaumann, R., Castillo-Rogez, J., Raymond, C. A., & Russell, C. T. (2020) Ceres’ partial differentiation: Undifferentiated crust mixing with a water-rich mantle. Astronomy & Astrophysics, 633, A117.Google Scholar

Neveu, M., & Desch, S. J. (2015) Geochemistry, thermal evolution, and cryovolcanism on Ceres with a muddy ice mantle. Geophysical Research Letters, 42, 10–197.Google Scholar

O’Brien, D. P., & Sykes, M. V. (2011) The origin and evolution of the asteroid belt – Implications for Vesta and Ceres. Space Science Reviews, 163, 41–61.Google Scholar

Park, R. S., Konopliv, A. S., Bills, B. G., et al. (2016) A partially differentiated interior for (1) Ceres deduced from its gravity field and shape. Nature, 537, 515–517.Google Scholar

Park, R. S., Konopliv, A. S., Ermakov, A. I., et al. (2020) Evidence of non-uniform crust of Ceres from Dawn’s high-resolution gravity data. Nature Astronomy, 4, 748–755.Google Scholar

Park, R. S., Vaughan, A. T., Konopliv, A. S., et al. (2019) High-resolution shape model of Ceres from stereophotoclinometry using Dawn Imaging Data. Icarus, 319, 812–827.Google Scholar

Prettyman, T. H., Mittlefehldt, D. W., Yamashita, N., et al. (2013) Neutron absorption constraints on the composition of 4 Vesta. Meteoritics & Planetary Science, 48, 2211–2236.Google Scholar

Prettyman, T. H., Yamashita, N., Toplis, M. J., et al. (2017) Extensive water ice within Ceres’ aqueously altered regolith: Evidence from nuclear spectroscopy. Science, 355, 55–59.Google Scholar

Preusker, F., Scholten, F., Matz, K. D., et al. (2016). Dawn at Ceres – Shape model and rotational state. Lunar and Planetary Science Conference, March, The Woodlands, TX, Vol. 47, Abstract 1954.Google Scholar

Quick, L. C., Buczkowski, D. L., Ruesch, O., et al. (2019) A possible brine reservoir beneath Occator crater: Thermal and compositional evolution and formation of the Cerealia Dome and Vinalia Faculae. Icarus, 320, 119–135.Google Scholar

Raymond, C. A., Ermakov, A. I., Castillo-Rogez, J. C., et al. (2020) Impact-driven mobilization of deep crustal brines on dwarf planet Ceres. Nature Astronomy, 4, 741–747.Google Scholar

Raymond, C. A., Jaumann, R., Nathues, A., et al. (2011) The Dawn topography investigation. In Russell, C. T., & Raymond, C. A. (eds.), The Dawn Mission to Minor Planets 4 Vesta and 1 Ceres. New York: Springer, pp. 487–510.Google Scholar

Raymond, C. A., Park, R. S., Asmar, S. W., et al. (2013) Vestalia Terra: An ancient mascon in the southern hemisphere of Vesta. Lunar and Planetary Science Conference, March, The Woodlands, TX, Vol. 44, Abstract 2882.Google Scholar

Raymond, C. A., Russell, C. T., & McSween, H. Y. (2017) Dawn at Vesta: Paradigms and paradoxes. In Elkins-Tanton, L. T., & Weiss, B. P. (eds.), Planetesimals: Early Differentiation and Consequences for Planets. Cambridge: Cambridge University Press, pp. 321–339.Google Scholar

Righter, K., & Drake, M. J. (1997) A magma ocean on Vesta: Core formation and petrogenesis of eucrites and diogenites. Meteoritics & Planetary Science, 32, 929–944.Google Scholar

Rivkin, A. S., Volquardsen, E. L., & Clark, B. E. (2006) The surface composition of Ceres: Discovery of carbonates and iron-rich clays. Icarus, 185, 563–567.Google Scholar

Ruesch, O., Genova, A., Neumann, W., et al. (2019) Slurry extrusion on Ceres from a convective mud-bearing mantle. Nature Geoscience, 12, 505–509.Google Scholar

Ruesch, O., Hiesinger, H., De Sanctis, M. C., et al. (2014) Detections and geologic context of local enrichments in olivine on Vesta with VIR/Dawn data. Journal of Geophysical Research: Planets, 119, 2078–2108.Google Scholar

Ruesch, O., Platz, T., Schenk, P., et al. (2016) Cryovolcanism on Ceres. Science, 353, aaf4286.Google Scholar

Russell, C. T., Raymond, C. A., Coradini, A., et al. (2012) Dawn at Vesta: Testing the protoplanetary paradigm. Science, 336, 684–686.Google Scholar

Ruzicka, A., Snyder, G. A., & Taylor, L. A. (1997) Vesta as the howardite, eucrite and diogenite parent body: Implications for the size of a core and for large‐scale differentiation. Meteoritics & Planetary Science, 32, 825–840.Google Scholar

Scott, E. R., Greenwood, R. C., Franchi, I. A., & Sanders, I. S. (2009) Oxygen isotopic constraints on the origin and parent bodies of eucrites, diogenites, and howardites. Geochimica et Cosmochimica Acta, 73, 5835–5853.Google Scholar

Scully, J. E., Buczkowski, D. L., Schmedemann, N., et al. (2017) Evidence for the interior evolution of Ceres from geologic analysis of fractures. Geophysical Research Letters, 44, 9564–9572.Google Scholar

Scully, J. E., Yin, A., Russell, C. T., et al. (2014) Geomorphology and structural geology of Saturnalia Fossae and adjacent structures in the northern hemisphere of Vesta. Icarus, 244, 23–40.Google Scholar

Smith, D. E., Zuber, M. T., Phillips, R. J., et al. (2012) Gravity field and internal structure of Mercury from MESSENGER. Science, 336, 214–217.Google Scholar

Sterenborg, M. G., & Crowley, J. W. (2013) Thermal evolution of early Solar System planetesimals and the possibility of sustained dynamos. Physics of the Earth and Planetary Interiors, 214, 53–73.Google Scholar

Thomas, P. C., Binzel, R. P., Gaffey, M. J., et al. (1997) Impact excavation on asteroid 4 Vesta: Hubble space telescope results. Science, 277, 1492–1495.Google Scholar

Thomas, P. C., Parker, J. W., McFadden, L. A., et al. (2005) Differentiation of the asteroid Ceres as revealed by its shape. Nature, 437, 224–226.Google Scholar

Tkalcec, B. J., Golabek, G. J., & Brenker, F. E. (2013) Solid-state plastic deformation in the dynamic interior of a differentiated asteroid. Nature Geoscience, 6, 93–97.Google Scholar

Travis, B. J., Bland, P. A., Feldman, W. C., & Sykes, M. V. (2018) Hydrothermal dynamics in a CM‐based model of Ceres. Meteoritics & Planetary Science, 53, 2008–2032.Google Scholar

Tricarico, P. (2013) Global gravity inversion of bodies with arbitrary shape. Geophysical Journal International, 195, 260–275.Google Scholar

Tricarico, P. (2014) Multi-layer hydrostatic equilibrium of planets and synchronous moons: Theory and application to Ceres and to Solar System moons. The Astrophysical Journal, 782, 99.Google Scholar

Tricarico, P. (2018) True polar wander of Ceres due to heterogeneous crustal density. Nature Geoscience, 11, 819–824.Google Scholar

Vaillant, T., Laskar, J., Rambaux, N., & Gastineau, M. (2019) Long-term orbital and rotational motions of Ceres and Vesta. Astronomy & Astrophysics, 622, A95.Google Scholar

Watts, A. B. (2001) Isostasy and Flexure of the Lithosphere. Cambridge: Cambridge University Press.Google Scholar

Wieczorek, M. A. (2015) Gravity and topography of the terrestrial planets. Treatise on Geophysics, 10, 165–206.Google Scholar

Wilson, L., & Keil, K. (2012) Volcanic activity on differentiated asteroids: A review and analysis. Geochemistry, 72, 289–321.Google Scholar

Zharkov, V. N., & Trubitsyn, V. P. (1978) Physics of Planetary Interiors. Astronomy and Astrophysics Series. Tucson, AZ: Pachart Pub House.Google Scholar

Zolotov, M. Y. (2009) On the composition and differentiation of Ceres. Icarus, 204, 183–193.Google Scholar

Zolotov, M. Y. (2020) The composition and structure of Ceres’ interior. Icarus, 335, 113404.Google Scholar

Zuber, M. T., McSween, H. Y., Binzel, R. P., et al. (2011) Origin, internal structure and evolution of 4 Vesta. Space Science Reviews, 163, 77–93.Google Scholar

Zuber, M. T., Smith, D. E., Neumann, G. A., et al. (2016) Gravity field of the Orientale basin from the Gravity Recovery and Interior Laboratory Mission. Science, 354, 438–441.Google Scholar

Zuber, M. T., Smith, D. E., Watkins, M. M., et al. (2013) Gravity field of the Moon from the Gravity Recovery and Interior Laboratory (GRAIL) mission. Science, 339, 668–671.Google Scholar

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Part II - Key Results from Dawn’s Exploration of Vesta and Ceres

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