Detection of rotational spectral variation on the M-type asteroid (16) Psyche
Metadata
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Sanchez, Juan A.
Reddy, Vishnu
Shepard, Michael K.
Thomas, Cristina
Cloutis, Edward A.
Takir, Driss
Conrad, Albert
Kiddell, Cain
Applin, Daniel
Date
2016-12-28Citation
Sanchez, J.A., V. Reddy, M.K. Shepard, C. Thomas, E.A. Cloutis, D. Takir, A. Conrad, C. Kiddell, and D. Applin. "Detection of rotational spectral variation on the M-type asteroid (16) Psyche." The Astronomical Journal 153 (1) (2017): 29 (8pp). DOI: 10.3847/1538-3881/153/1/29.
Abstract
The asteroid (16) Psyche is of scientific interest because it contains ∼1% of the total mass of the asteroid belt and is thought to be the remnant metallic core of a protoplanet. Radar observations have indicated the significant presence of metal on the surface with a small percentage of silicates. Prior ground-based observations showed rotational variations in the near-infrared (NIR) spectra and radar albedo of this asteroid. However, no comprehensive study that combines multi-wavelength data has been conducted so far. Here we present rotationally resolved NIR spectra (0.7–2.5 μm) of (16) Psyche obtained with the NASA Infrared Telescope Facility. These data have been combined with shape models of the asteroid for each rotation phase. Spectral band parameters extracted from the NIR spectra show that the pyroxene band center varies from ∼0.92 to 0.94 μm. Band center values were used to calculate the pyroxene chemistry of the asteroid, whose average value was found to be Fs30En65Wo5. Variations in the band depth (BD) were also observed, with values ranging from 1.0% to 1.5%. Using a new laboratory spectral
calibration method, we estimated an average orthopyroxene content of 6% ± 1%. The mass-deficit region of Psyche, which exhibits the highest radar albedo, also shows the highest value for the spectral slope and the minimum BD. The spectral characteristics of Psyche suggest that its parent body did not have the typical structure expected for a differentiated body or that the sequence of events that led to its current state was more complex than previously thought.