Longitudinal heterogeneity of Phobos’ crater size-frequency distribution: coevolution of resurfacing and orbital dynamics

• Published in: Progress in earth and planetary science Vol. 12; no. 1; pp. 68 - 14
• Main Authors: Uchida, Yuki, Toyokawa, Kosei, Usui, Tomohiro, Suzuki, Yudai, Tabata, Haruhisa
• Format: Journal Article
• Language: English
• Published: Berlin/Heidelberg Springer Berlin Heidelberg 01.12.2025; Springer Nature B.V; SpringerOpen
• Subjects: 1. Space and planetary sciences; Asymmetry; Atmospheric Sciences; Biogeosciences; Crater density; Craters; Earth and Environmental Science; Earth Sciences; Ejecta blanket; Evolution; Frequency distribution; Geophysics/Geodesy; Gravity; Heterogeneity; Hydrogeology; Mars; MMX; Moon; Phobos; Phobos ejecta; Planetology; Planets; Progress on science and instruments for Martian Moons eXploration (MMX) mission; Research Article; Stickney crater; Tidal lock; Ejecta blanket; Secondary impacts; MMX; Regolith layer; Phobos ejecta; Tidal lock; Crater density; Stickney crater
• ISSN: 2197-4284; 2197-4284
• DOI: 10.1186/s40645-025-00741-3

Phobos always keeps the same side facing its host planet like Earth’s Moon, making it a key comparative target for studying the coevolution of planet–satellite systems. The heterogeneity of satellite surface evolution under a host planet’s gravity is crucial for understanding the evolution of such systems. This study examines the crater size–frequency distribution (CSFD) across four equatorial regions of Phobos—leading, near, trailing, and far sides—to investigate surface evolution heterogeneities linked to resurfacing and orbital dynamics following the formation of its largest crater, Stickney. We focus on the crater size indicating the number of craters lower than expected from the production function (PF) model. We also estimate the crater erasure scale due to the ejecta blanket and assess deviations in the size–frequency distribution (SFD) of impactors from the PF model. This study shows three main conclusions about surface heterogeneity in Phobos’ CSFD and ejecta blanket thickness. (1) The leading side experienced significant crater erasure, likely due to the thickest ejecta blanket from the Stickney impact. (2) The density of craters larger than ∼ 1.5 km reflects pre-Stickney conditions, whereas the densities of craters measuring 0.8–1.5 km and 400–800 m in diameter reflect post-Stickney surface evolution. (3) Crater number density on the near side was consistently lower than on the far side, likely due to planetary screening. This reduction in crater formation on the near side is particularly attributed to its proximity to Mars. Our results suggest that the leading side experienced the greatest deposition of the ejecta blanket on Phobos. This deposition likely occurred immediately after Stickney’s formation, followed by global resurfacing facilitated by Phobos’ post-Stickney impact spin. One possible explanation for the scarcity of craters smaller than 800 m is that later-arriving, low-energy impacts erased smaller preexisting craters while leaving larger ones comparatively well preserved, leading to a net reduction in their population.