Abstract
Organic matter directly observed at the surface of an inner planetary body is quite infrequent due to the usual low abundance of such matter and the limitation of the infrared technique. Fortuitously, the Dawn mission has revealed, thanks to the Visible and InfraRed mapping spectrometer (VIR), large areas rich in organic matter at the surface of Ceres, near Ernutet crater. The origin of the organic matter and its abundance in association with minerals, as indicated by the low altitude VIR data, remains unclear, but multiple lines of evidence support an endogenous origin. Here, we report an experimental investigation to determine the abundance of the aliphatic carbon signature observed on Ceres. We produced relevant analogues containing ammoniated-phyllosilicates, carbonates, aliphatic carbons (coals), and magnetite or amorphous carbon as darkening agents, and measured their reflectance by infrared spectroscopy. Measurements of these organic-rich analogues were directly compared to the VIR spectra taken from different locations around Ernutet crater. We found that the absolute reflectance of our analogues is at least two orders of magnitude higher than Ceres, but the depths of absorption bands match nicely the ones of the organic-rich Ceres spectra. The choices of the different components are discussed in comparison with VIR data. Relative abundances of the components are extrapolated from the spectra and mixture composition, considering that the differences in reflectance level is mainly due to optical effects. Absorption bands of Ceres’ organic-rich spectra are best reproduced by around 20 wt.% of carbon (a third being aliphatic carbons), in association with around 20 wt.% of carbonates, 15 wt.% of ammoniated-phyllosilicate, 20 wt.% of Mg-phyllosilicates, and 25 wt.% of darkening agent. Results also highlight the pertinence to use laboratory analogues in addition to models for planetary surface characterization. Such large quantities of organic materials near Ernutet crater, in addition to the amorphous carbon suspected on a global scale, requires a concentration mechanism whose nature is still unknown but that could potentially be relevant to other large volatile-rich bodies.
Highlights
This article is an open access articleCeres is the only dwarf planet of the asteroid belt
We report spectral measurements obtained on laboratory analogues rich in aliphatic carbons for comparison with the signatures obtained at Ceres
There are local variations in the surface mineralogy and one is clearly visible in Ernutet crater, where a fifth component is needed to fit an additional band at 3.4 μm (Figure 1)
Summary
Ceres is the only dwarf planet of the asteroid belt. Before the arrival of the DAWN mission, ground-based observations had already indicated spectral properties and composition close to CI chondrites, with most likely ammoniated Mg-bearing clays [1,2]. Results obtained from the Gamma Ray Neutron Detector (GRaND) that probed Ceres’ regolith to 0.5–1 m depth have shown the occurrence of amorphous carbon everywhere with average abundances between 8 and 14 wt.% [17] This is larger than the bulk quantity of carbon in carbonaceous chondrites meteorites (CI up to 4–5 wt.% [18]). There are local variations in the surface mineralogy and one is clearly visible in Ernutet crater, where a fifth component is needed to fit an additional band at 3.4 μm (Figure 1) This component is ascribed to an organic material containing aliphatic carbon [14]. We report these results and discuss modeling results and implications for Ceres’ composition
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