Abstract
Abstract The asteroid (16) Psyche is the largest of the M-type asteroids, which have been hypothesized to be the cores of disrupted planetesimals and the parent bodies of the iron meteorites. While recent evidence has collected against a pure metal composition for Psyche, its spectrum and radar properties remain anomalous. We observed (16) Psyche in thermal emission with the Atacama Large Millimeter/submillimeter Array at a resolution of 30 km over two-thirds of its rotation. The diurnal temperature variations are at the ∼10 K level over most of the surface and are best fit by a smooth surface with a thermal inertia of 280 ± 100 J m−2 K−1 s−1/2. We measure a millimeter emissivity of 0.61 ± 0.02, which we interpret via a model that treats the surface as a porous mixture of silicates and metals, where the latter may take the form of iron sulfides/oxides or, alternatively, conducting metallic inclusions. The emissivity indicates a metal content of no less than 20% and potentially much higher, but the polarized emission that should be present for a surface with ≥20% metal content is almost completely absent. This requires a highly scattering surface, which may be due to the presence of reflective metallic inclusions. If such is the case, a consequence is that metal-rich asteroids may produce less polarized emission than metal-poor asteroids, exactly the opposite prediction from standard theory, arising from the dominance of scattering over the bulk material properties.
Highlights
Our Solar System’s population of asteroids represents the remnant fragments of the planetesimals, and encodes the history of the thermal and collisional evolution of the inner Solar System (e.g. Wetherill & Chapman 1988)
For a thermophysical model with thermal inertia, surface roughness, and dielectric constant as the three free parameters, we find a best-fit thermal inertia of Γ=210±60, a smooth surface texture, and a dielectric constant of =21±1
The best-fit model does not provide a good fit to the variation in brightness with emission angle; residuals from even the best-fit models show a dark ring around the limb, indicating that the model is overpredicting either the temperature or the emissivity at high emission angles
Summary
Our Solar System’s population of asteroids represents the remnant fragments of the planetesimals, and encodes the history of the thermal and collisional evolution of the inner Solar System (e.g. Wetherill & Chapman 1988). The M-type asteroids (Tholen 1984; a subset of the X complex, Bus & Binzel 2002; DeMeo et al 2009) are hypothesized to be the remnant core fragments of these differentiated objects, and the parent bodies of the iron meteorites (Chapman & Salisbury 1973; Johnson & Fanale 1973; Gaffey & McCord 1978; Bell et al 1989). The M-type asteroids show red sloped, nearly featureless optical-near-infrared spectra, which are characteristic of the iron meteorites (Cloutis et al 1990). These asteroids are characterized by high radar albedos, which imply higher surface bulk densities than typical asteroids. Psyche’s bulk density of 3.78±0.34 g/cm (Elkins-Tanton et al 2020) is consistent with its surface density, implying minimal increase in density with depth
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