High‐Resolution Thermophysical Analysis of the OSIRIS‐REx Sample Site and Three Other Regions of Interest on Bennu

The OSIRIS‐REx (Origins, Spectral Interpretation, Resource Identification, and Security–Regolith Explorer) spacecraft sampled asteroid (101955) Bennu on 20 October 2020 and will return the collected regolith to Earth in 2023. Before sample collection, spectral observations of four regions of interes...

Full description

Saved in:
Bibliographic Details
Published in:Journal of geophysical research. Planets 2022-06, Vol.127 (6), p.n/a
Main Authors: Rozitis, B., Ryan, A. J., Emery, J. P., Nolan, M. C., Green, S. F., Christensen, P. R., Hamilton, V. E., Daly, M. G., Barnouin, O. S., Lauretta, D. S.
Format: Article
Language:English
Subjects:
Altimetry
Apollo asteroids
Asteroids
Bennu
Boulders
Brightness temperature
Carbonates
Infrared instruments
Laser altimeters
Lasers
Maximum temperatures
Meteorites
Meteors & meteorites
Modelling
Numerical simulations
Organic compounds
Origins
OSIRIS‐REx
Physical properties
Porosity
Regolith
Sample return missions
sample site
Security
Spacecraft
Spatial resolution
Specific heat
Surface temperature
temperature
Terrain models
Thermal inertia
Thermal properties
Thermodynamic properties
Thermophysical models
Thermophysical properties
Topography
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The OSIRIS‐REx (Origins, Spectral Interpretation, Resource Identification, and Security–Regolith Explorer) spacecraft sampled asteroid (101955) Bennu on 20 October 2020 and will return the collected regolith to Earth in 2023. Before sample collection, spectral observations of four regions of interest on Bennu's surface were acquired at high spatial resolution (2–9 m per spectrometer spot) to identify the most suitable site for sampling and provide contextual information for the returned sample. In this study, we investigate thermal‐infrared (6–50 μm) observations of these four regions, including the site that OSIRIS‐REx ultimately sampled, using the Advanced Thermophysical Model with input digital terrain models derived from laser altimetry. From model‐to‐measurement comparisons, we find that the observed brightness temperatures depend strongly on small‐scale topography, local variations in thermal inertia, and the observation phase angle. Thermal inertia mapping reveals spatial variations that distinguish the different boulder types found on Bennu. A boulder bearing carbonate veins has higher thermal inertia than average, suggesting that cementation processes reduced its porosity. The thermal inertia of the site sampled is 190 ± 30 J m−2 K−1 s−1/2, which is consistent with observations of a fine‐grained regolith mixed with porous rocks. Thermophysical modeling of the site sampled predicts that the maximum temperatures experienced by the collected sample while on Bennu were 357 ± 3 and 261 ± 3 K for the surface and 50 cm depth, respectively. We predict that OSIRIS‐REx will return a sample with thermophysical properties unique from those of meteorites. Plain Language Summary Thermal inertia is a physical characteristic of materials that, along with topography, controls how the surface temperature of a planetary body changes from day to night. On asteroids like Bennu, the target of the Origins, Spectral Interpretation, Resource Identification, and Security–Regolith Explorer (OSIRIS‐REx) sample return mission, thermal inertia is dictated by several properties of the surface, such as the porosity and abundance of boulders and the size of smaller particles. Thermal inertia is quantified by running numerical simulations of asteroid surface temperatures and comparing the results to the observed temperatures collected by a thermal‐infrared instrument onboard the OSIRIS‐REx spacecraft. Here, we ran a very high‐resolution temperature model, using topographic data fr
ISSN:2169-9097
2169-9100
DOI:10.1029/2021JE007153