Ice? Salt? Pressure? Sediment deformation structures as evidence of late-stage shallow groundwater in Gale crater, Mars

Geology Pub Date : 2024-03-22 DOI:10.1130/g51849.1
S. G. Banham, Amelie L. Roberts, Sanjeev Gupta, Joel M. Davis, Lucy M. Thompson, D. M. Rubin, G. Paar, K. Siebach, W. Dietrich, A. Fraeman, A. Vasavada
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Abstract

Persistence of near-surface water during the late evolution of Gale crater, Mars, would have been fundamental for maintaining a habitable environment. Sedimentation in aqueous conditions is evident during the early stages of crater infilling, where accumulation of lower Mount Sharp group strata is characterized by fluviolacustrine sedimentary rocks. The basal unit of the Siccar Point group—the Stimson formation—which unconformably overlies the Mount Sharp group and represents conditions postdating the exhumation of Aeolis Mons, is characterized by accumulation of aeolian strata under arid conditions. Water was largely absent near the surface during its deposition. At the Feòrachas outcrop, discovery of soft sediment deformation structures in aeolian Stimson strata challenges the notion that Gale crater was devoid of water during its later depositional phase. We identified deformed wind-rippled and vertically laminated sandstones, hosted within erosion-resistant ridges forming boxwork patterns. Broadly, these structures are diagnostic of water (as liquid or as ice) in the shallow subsurface. Comparison with Earth analogues suggests formation by subsurface fluid escape, freeze-thaw processes, or evaporite deformation. Regardless of the mechanism, these structures signify the presence of water at or near the surface much later than previously documented and may extend the habitability window in Gale crater.
冰?盐?压力?沉积物变形结构是火星盖尔陨石坑晚期浅层地下水的证据
在火星盖尔陨石坑的晚期演化过程中,近地表水的持续存在对于维持宜居环境至关重要。在陨石坑填充的早期阶段,水环境下的沉积作用非常明显,夏普山组下部地层的堆积特征是流砂岩沉积岩。Siccar Point 组的基底单元--Stimson 层--与夏普山组互不成层,代表了 Aeolis Mons 被掘起之后的情况,其特征是干旱条件下风化地层的堆积。在其沉积过程中,地表附近基本没有水。在 Feòrachas 露头,在 Stimson 风化层中发现了软沉积物变形结构,这对盖尔陨石坑后期沉积阶段没有水的说法提出了质疑。我们发现了变形的风裂砂岩和垂直层状砂岩,它们位于形成箱形图案的抗侵蚀山脊中。从广义上讲,这些结构是浅层地下水(液态或冰态)的特征。与地球上的类似结构相比,这些结构是由地下流体逸出、冻融过程或蒸发岩变形形成的。不管是哪种机制,这些结构都表明在地表或地表附近有水存在,这比以前的记录要晚得多,而且可能会延长盖尔陨石坑的可居住性窗口期。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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