Now Reading: Martian Concretion Sizes Predicted From Two Independently Constrained Inputs: Atmospheric Dust Grain Size And Obliquity-forced Wetting Duration
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Martian Concretion Sizes Predicted From Two Independently Constrained Inputs: Atmospheric Dust Grain Size And Obliquity-forced Wetting Duration
Martian Concretion Sizes Predicted From Two Independently Constrained Inputs: Atmospheric Dust Grain Size And Obliquity-forced Wetting Duration
(Left) Predicted concretion diameter for different nucleation density scaling exponents α. For α ≤ 1, diffusion controls at the Mars dust grain size and predictions match observations (green band). For α ≥ 1.5, nucleation dominates even at 3 µm, predicting concretions well below the observed range, ruled out by the data. (Right) Crossover grain size as a function of α (log scale). Green region: diffusion-limited zone (crossover above Mars dust at 3 µm). Pink region: nucleation-limited zone. The graincontact derivation (dotted line, α = 1) sits within the diffusion-limited zone, consistent with observations. — astro-ph.EP
Diagenetic concretions have been identified at multiple widely separated sites on Mars, including Meridiani Planum (Opportunity), Gale crater (Curiosity), and Jezero crater (Perseverance).
Solid concretions at all sites fall within the millimetre size range (typically 1-6 mm diameter), despite differing cement mineralogies. The one substantial outlier — centimetre-to-decimetre-scale hollow concretions on Bradbury Rise — formed in coarser basaltic sandstone via a distinct mechanism.
I propose that this size convergence reflects a common physical control: the globally uniform fraction of ultra-fine (~3 um), amorphous, equant atmospheric dust incorporated into sediments at all sites. I derive the diagenetic timescale from Mars’ ~120 kyr obliquity cycle, which drives periodic subsurface wetting: each high-obliquity pulse (~10^4-10^5 yr) sets the available growth time. Using a diffusion-reaction model with nucleation competition, I show that the low effective diffusivity imposed by the fine dust matrix limits concretion growth to the observed millimetre scale, independent of local fluid chemistry.
Formation efficiency in dust-rich sediment exceeds 90%, making concretion formation essentially inevitable wherever liquid water contacts the dust. This mechanism depends on the non-phyllosilicate, equant-grain mineralogy of Martian dust, which maintains connected pore networks unlike terrestrial clays.
Growth is self-limiting: the first wetting pulse exhausts reactive phases in the depletion halo, so successive obliquity cycles produce new concretions in fresh sediment rather than enlarging existing ones. Each concretion records a single wetting episode. The narrow size distributions at all sites suggest that Martian concretion populations may constitute a sedimentary archive of the planet’s obliquity history.
Samuel Cody
Comments: 19 pages, 3 figures, 2 tables. Preprint; not yet peer-reviewed
Subjects: Earth and Planetary Astrophysics (astro-ph.EP)
Cite as: arXiv:2603.11143 [astro-ph.EP] (or arXiv:2603.11143v1 [astro-ph.EP] for this version)
https://doi.org/10.48550/arXiv.2603.11143
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Submission history
From: Samuel Cody
[v1] Wed, 11 Mar 2026 17:06:29 UTC (964 KB)
https://arxiv.org/abs/2603.11143
Astrobiology,
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