Abstract
The otherwise homogeneous surface of Ceres is dotted with hundreds of anomalously bright, predominantly carbonate-bearing areas, termed “faculae,” with Bond albedos ranging from ∼0.02 to >0.5. Here, we classify and map faculae globally to characterize their geological setting, assess potential mechanisms for their formation and destruction, and gain insight into the processes affecting the Ceres surface and near-surface. Faculae were found to occur in four distinct geological settings, associated predominantly with impact craters: (1) crater pits, peaks, or floor fractures (floor faculae), (2) crater rims or walls (rim/wall faculae), (3) bright ejecta blankets, and (4) the mountain Ahuna Mons. Floor faculae were identified in eight large, deep, and geologically young (asteroid-derived model (ADM) ages of <420 ± 60 Ma) craters: Occator, Haulani, Dantu, Ikapati, Urvara, Gaue, Ernutet, and Azacca. The geometry and geomorphic features of the eight craters with floor faculae are consistent with facula formation via impact-induced heating and upwelling of volatile-rich materials, upwelling/excavation of heterogeneously distributed subsurface brines or their precipitation products, or a combination of both processes. Rim/wall faculae and bright ejecta occur in and around hundreds of relatively young craters of all sizes, and the geometry of exposures is consistent with facula formation via the excavation of subsurface bright material, possibly from floor faculae that were previously emplaced and buried. A negative correlation between rim/wall facula albedo and crater age indicates that faculae darken over time. Models using the Ceres crater production function suggest initial production or exposure of faculae by large impacts, subsequent dissemination of facula materials to form additional small faculae, and then burial by impact-induced lateral mixing, which destroys faculae over timescales of less than 1.25 Gyr. Cumulatively, these models and the observation of faculae limited to geologically young craters indicate relatively modern formation or exposure of faculae, indicating that Ceres’ surface remains active and that the near surface may support brines in the present day.
Highlights
Faculae were found to fall into four distinct geological classes: (1) crater pits, peaks, or floor fractures, (2) crater rims or walls, (3) bright ejecta blankets, and (4) the mountain Ahuna Mons
The geometry of craters with floor faculae is consistent with their formation via the impact-induced heating and upwelling of subsurface volatiles, the upwelling of volatile-rich brines along impact-induced fractures or as low-density plumes, or some combination of these processes
The association of floor faculae craters with features consistent with upwelling materials and the young age of floor faculae relative to their parent craters indicate that the impact-initiated upwelling of extant subsurface brines may be the favored crater floor faculae formation mechanism
Summary
The average geometric albedo measured by Dawn’s Visible and Infrared spectrometer (VIR) at. 0.55 μm is 0.094 ± 0.008, and the average bond albedo measured with the Framing Camera (FC) clear filter is 0.034 ± 0.001 (Ciarniello et al, 2017; Ammannito et al, 2016; Li et al, 2016). Since Dawn’s initial investigation of Occator crater, the FC has imaged the entire illuminated surface at a resolution of ∼35 m/pixel in clear filter. These images have revealed the presence of hundreds of faculae and bright ejecta associated with impact craters. By characterizing the mechanisms by which bright materials are emplaced, we can better understand the composition and structure of the subsurface and the processes that shape Ceres’ surface. Results are used to investigate potential mechanisms for the formation and destruction of faculae and the processes that modify them over time
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