Seasonal erosion and restoration of the dust cover on comet 67P/Churyumov-Gerasimenko as observed by OSIRIS onboard Rosetta

Hu, Xuanyu; Shi, Xian; Sierks, H.; Fulle, M.; Blum, Jürgen; Keller, H. U.; Kührt, Ekkehard; Davidsson, B.; Güttler, C.; Gundlach, Bastian; Pajola, M.; Bodewits, Dennis; Vincent, J. B.; Oklay, N.; Massironi, Matteo; Fornasier, S.; Tubiana, C.; Groussin, O.; Boudreault, S.; Höfner, Sebastian; Mottola, S.; Barbieri, C.; Lamy, Philippe; Rodrigo, R.; Koschny, D.; Rickman, H.; A’Hearn, Michael F.; Agarwal, Jessica; Barucci, Maria Antonietta; Bertaux, Jean-Loup; Bertini, Ivano; Cremonese, G.; Deppo, Vania Da; Debei, S.; Cecco, M. De; Deller, Jakob; El‐Maarry, M. R.; Gicquel, A.; Gutiérrez-Marques, P.; Gutiérrez, P. J.; Hofmann, M.; Hviid, S. F.; Ip, W.-H.; Jordá, L.; Knollenberg, J.; Kovács, Gábor; Kramm, J. R.; Küppers, M.; Lara, L. M.; Lazzarin, M.; Moreno, J. J. Lopez; Marzari, F.; Naletto, G.; Thomas, N.

doi:10.1051/0004-6361/201629910

Cited by 50 publications

(52 citation statements)

References 71 publications

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“…We have evidence [6], in fact, that water ice-rich layers are immediately available under the dust layer, as shown in areas of recent disruption of the surface [23] and as demonstrated by many thermal models applied to cometary nuclei [24,25]. Between 20% [21] to 50% [26] of the dust grains ejected around perihelion from the south pole, the region which receives the maximum insolation at that time, fall-back preferentially on the northern hemisphere. The fall-back flux is dominated by decimetre-sizes dust aggregates in which a small fraction of water ice can be maintained [21].…”

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confidence: 63%

An orbital water-ice cycle on comet 67P from colour changes

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Capaccioni

Ciarniello

et al. 2020

Nature

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The solar heating reaching a cometary surface provides the energy input necessary to sustain gaseous activity through which dust is removed from the nucleus [1,2]. In this dynamical environment, both coma [3,4] and nucleus [5,6] evolve during the orbit, changing their physical and compositional properties. The environment encircling an active cometary nucleus is populated by dust grains with complex and variegated shapes [7] lifted and diffused by gases freed from the sublimation of surface ices [8,9]. Visible colour of dust particles is highly variable: carbonaceous-organic material-rich grains [10] appear red while Mg-silicate [11,12] or water ice [13,14] rich grains are blue with further dependence from grain size distribution, viewing geometry, activity level and comet family type. By integrating spacecraft with telescopic data from the Earth, we know that local colour changes are associated with grain size variations, like in the bluer jets made of submicron grains on comet Hale-Bopp [15] or in fragmented grains on C/1999 S4 (LINEAR) coma [16]. Apart from grain size, also composition influences coma's colour response because transparent volatiles can introduce a significant blueing in scattered light as observed in the dust particles ejected after Deep Impact event [17]. Here we report about the observation of two opposite seasonal colour cycles developing in the coma dust particles and on the surface of comet 67P/CG (Churyumov-Gerasimenko) as observed by Rosetta spacecraft during its perihelion passage in 2015 [18]. Spectral analysis indicates an enrichment of submicron grains made of organic material and amorphous carbon in the coma causing the escalating colour reddening observed during the perihelion passage. At the same time, the progressive removal of dust from the nucleus causes the exposure of more pristine and bluish icy layers on the surface. Far from the Sun, we find that the abundance of water ice on the nucleus is reduced due to redeposition of dust and/or dehydration of the surface layer while water ice contribute to less-red coma's colours. MAIN TEXT Understanding how comets work and evolve is one of the most compelling questions to which the Rosetta mission [18] has been trying to answer. Unlike past flyby missions to comets, Rosetta was designed to enter the same orbit and accompany 67P through its perihelion passage giving us the unique opportunity to follow the colour changes developing on a comet nucleus and coma in its active phase through the inner Solar System. So far, several studies have investigated how dust and gas (H 2 O, CO 2) production [3] are correlated among them during one cometary rotation showing that the water ice sublimation on 67P surface is the driving mechanism for dust ejection in the coma [2]. In fact, the dust emission flux appears lower above high-cohesion consolidated terrains while it is maximum when the subsolar direction is aligned above volatile-rich areas. Since the illumination conditions continuously change on 67P, rather than focusing on coma and nucleus ...

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confidence: 63%

An orbital water-ice cycle on comet 67P from colour changes

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Capaccioni

Ciarniello

et al. 2020

Nature

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“…Seasonal variations of the cover by back fall were observed at several places particularly at northern mid latitudes. The thickness of the cover was estimated to 0.5 to 1 m (Hu et al 2017). A more precise measure of 1.4 m could be derived for the variation of the ground level at Hapi using the height of outcrops (Cambianica et al 2020).…”

Section: Determination Of the Nucleus Physical Properties And Mineralogymentioning

confidence: 99%

Cometary Nuclei—From Giotto to Rosetta

Keller

Kührt

2020

Space Sci Rev

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We will briefly recapitulate the beginning of modern cometary physic. Then we will assess the results of the cometary flyby missions previous to ESA's Rosetta rendezvous with comet 67P/Churyumov-Gerasimenko. Emphasis is given to the physical properties of cometary nuclei. We will relate the results of the Rosetta mission to those of the flybys. A major conclusion is that the visited cometary nuclei seem to be alike but represent different stages of evolution. Coma composition and appearance are not only controlled by the composition of the nucleus but also strongly influenced by the shape and rotation axis orientation of the nucleus and resulting seasons that generate varying surface coverage by back fall material. Rosetta showed that the coma composition is not only varying spatially but also strongly with time during the perihelion passage. Hence past interpretations of cometary coma observations have to be reconsidered. Finally, we will try to assess the impact of the cornerstone mission leading to a critical evaluation of the mission results. Lessons learned from Rosetta are discussed; major progress and open points in cometary research are reviewed. Keywords Comets • 67P/Churyumov-Gerasimenko • Cometary nuclei • Rosetta mission 1 History of Cometary Physics Comets display a unique spectacle on the night sky. Usually they appear like a faint star during their discovery and later move fast across the night sky becoming brighter when

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“…Instead, many rapid changes were detected in what were previously thought to be the comparably inactive smooth terrains. These changes occurred in the the months leading up to perihelion and include both morphological changes like depressions (El‐Maarry et al, ; Groussin et al, ) and “honeycombs” (Hu et al, ) and spectroscopic (De Sanctis et al, ; Fornasier et al, ). Together, these changes suggest the nucleus removed an overlaying layer of dust prior to receiving its newest layer at perihelion.…”

Section: Introductionmentioning

confidence: 99%

Migrating Scarps as a Significant Driver for Cometary Surface Evolution

Birch

Hayes

Umurhan

et al. 2019

Geophysical Research Letters

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Rosetta observations of 67P/Churyumov‐Gerasimenko (67P) reveal that most changes occur in the fallback‐generated smooth terrains, vast deposits of granular material blanketing the comet's northern hemisphere. These changes express themselves both morphologically and spectrally across the nucleus, yet we lack a model that describes their formation and evolution. Here we present a self‐consistent model that thoroughly explains the activity and mass loss from Hapi's smooth terrains. Our model predicts the removal of dust via reradiated solar insolation localized within depression scarps that are substantially more ice rich than previously expected. We couple our model with numerous Rosetta observations to thoroughly capture the seasonal erosion of Hapi's smooth terrains, where local scarp retreat gradually removes the uppermost dusty mantle. As sublimation‐regolith interactions occur on rocky planets, comets, icy moons, and Kuiper belt objects, our coupled model and observations provide a foundation for future understanding of the myriad of sublimation‐carved worlds.

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Seasonal erosion and restoration of the dust cover on comet 67P/Churyumov-Gerasimenko as observed by OSIRIS onboard Rosetta

Cited by 50 publications

References 71 publications

An orbital water-ice cycle on comet 67P from colour changes

An orbital water-ice cycle on comet 67P from colour changes

Cometary Nuclei—From Giotto to Rosetta

Migrating Scarps as a Significant Driver for Cometary Surface Evolution

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