Asteroid 16 Psyche: Shape, Features, and Global Map

TL;DR

This study constructs a detailed 3D shape model of asteroid 16 Psyche using multi-wavelength observations, maps its surface features, and analyzes its composition, suggesting it may be a differentiated metallic core or a remnant core with localized metal-rich regions.

Contribution

The paper provides the first comprehensive shape model and global map of Psyche integrating diverse observational data, and offers new insights into its surface composition and geological features.

Findings

Psyche's dimensions are approximately 278x238x171 km.

Radar albedo suggests significant metal content in the regolith.

Surface features include regions of high optical and radar albedo.

Abstract

We develop a shape model of asteroid 16 Psyche using observations acquired in a wide range of wavelengths: Arecibo S-band delay-Doppler imaging, Atacama Large Millimeter Array (ALMA) plane-of-sky imaging, adaptive optics (AO) images from Keck and the Very Large Telescope (VLT), and a recent stellar occultation. Our shape model has dimensions 278 (-4/+8) km x 238 (-4/+6) km x 171 (-1/+5) km, an effective spherical diameter Deff = 222 -1/+4 km, and a spin axis (ecliptic lon, lat) of (36 deg, -8 deg) +/- 2 deg. We survey all the features previously reported to exist, tentatively identify several new features, and produce a global map of Psyche. Using 30 calibrated radar echoes, we find Psyche's overall radar albedo to be 0.34 +/- 0.08 suggesting that the upper meter of regolith has a significant metal (i.e., Fe-Ni) content. We find four regions of enhanced or complex radar albedo, one of which correlates well with a previously identified feature on Psyche, and all of which appear to correlate with patches of relatively high optical albedo. Based on these findings, we cannot rule out a model of Psyche as a remnant core, but our preferred interpretation is that Psyche is a differentiated world with a regolith composition analogous to enstatite or CH/CB chondrites and peppered with localized regions of high metal concentrations. The most credible formation mechanism for these regions is ferrovolcanism as proposed by Johnson et al. (Nature Astronomy vol 4, January 2020, 41-44).