Post-impact thermal structure and cooling timescales of Occator crater on asteroid 1 Ceres
Abstract
Occator crater is perhaps the most distinct surface feature observed by NASA's Dawn spacecraft on the Cerean surface. Contained within the crater are the highest albedo features on the planet, Cerealia Facula and Vinalia Faculae, and relatively smooth lobate flow deposits. We present hydrocode simulations of the formation of Occator crater, varying the water to rock ratio of our pre-impact Cerean surface. We find that at water to rock mass ratios up to 0.3, sufficient volumes of Occator's post-impact subsurface would be above the melting point of water to allow for the deposition of faculae-like deposits via impact-heat driven hydrothermal effusion of brines. This reservoir of hydrothermally viable material beneath the crater is composed of a mixture of impactor material and material uplifted from 10‧s of kilometers beneath the pre-impact surface, which could sample a deep subsurface volatile reservoir, if present. Using a conductive cooling model, we estimate that the lifetime of hydrothermal activity within such a system, depending on choice of material constants, is between 0.4 and 4 Myr. Our results suggest that impact heating from the Occator forming impact provides a viable mechanism for the creation of the observed faculae, with the proviso that the faculae formed within a relatively short time window after the crater itself formed.
- Publication:
-
Icarus
- Pub Date:
- March 2019
- DOI:
- 10.1016/j.icarus.2018.08.028
- Bibcode:
- 2019Icar..320..110B
- Keywords:
-
- Asteroid Ceres;
- Asteroids Impact Processes