Stable Brine Layers beneath Europa’s Chaos

Chivers, C. J.; Buffo, J. J.; Schmidt, B. E.

doi:10.3847/psj/acea75

Cited by 5 publications

(2 citation statements)

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“…Hydrated salt minerals are inferred to be present in low albedo regions of Europa's surface (Kargel et al, 2000;McCord et al, 1999) sometimes on double ridges (Prockter & Patterson, 2009) and may be sourced from the subsurface ocean (Zolotov & Shock, 2001). In the case of local sourcing from briny sills in the shell (Chivers et al, 2023), the crack is assumed to have originated at the surface and propagated downward. Salts may be more likely to be erupted onto the surface in this case because the conditions necessary for the eruption are more realistically achieved (Lesage et al, 2020(Lesage et al, , 2021Quick & Hedman, 2020).…”

Section: Discussionmentioning

confidence: 99%

Europa's Double Ridges Produced by Ice Wedging

Cashion,

Johnson,

Gibson

et al. 2024

JGR Planets

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Double ridges are sprawling features observed globally across the icy surface of Europa. They consist of two topographic highs flanking a trough. The topographic relief of the ridges is approximately 100 m, and the ridges extend up to hundreds of kilometers in length. The interior structure and dynamics of Europa's ice shell are currently poorly constrained. Therefore, accurate models for the formation of these prominent surface features can be useful for determining how the ice shell operates. We hypothesize that double ridges form as a result of incremental ice wedging. We use both analytical and numerical finite element models to quantify the deformation that occurs as an ice wedge grows incrementally within the ice shell. We show that incremental growth of the ice wedge results in surface deformation that matches the size and shape of typical Europan double ridges, including their topographic relief and surrounding troughs. We find that as the depth of the ice wedge increases, double ridges become broader and shorter. We explore the possibility of local and non‐local sources for the liquid water that freezes to produce the wedge and ultimately argue in favor of local sources of liquid water within the ice shell.

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Section: Discussionmentioning

confidence: 99%

Europa's Double Ridges Produced by Ice Wedging

Cashion,

Johnson,

Gibson

et al. 2024

JGR Planets

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“…Given the variable thickness of ice shells (Billings & Kattenhorn, 2005; Giese et al., 2008; Olgin et al., 2011) and the challenges associated with it in exploring the subsurface ocean, the existence of a stable body of liquid water in an ice shell may make for a more realistic environment for future exploration. In searching for life, melt ponds (Chivers et al., 2023) may be their own potentially habitable niches, separate from the ocean on icy satellites. Closer to the surface, melt ponds would be more likely to contain radiolytically produced oxidants and exogenic material from the surrounding environment.…”

Section: Introductionmentioning

confidence: 99%

Frictional Strength, Stability, and Potential Shear Heating on Icy Satellite Faults

Zaman,

McCarthy,

Skarbek

et al. 2024

JGR Planets

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We determined the frictional strength and stability of polycrystalline ice and ice‐ammonia to constrain fault behavior on icy satellites such as Enceladus and Europa. Friction experiments including velocity steps and slide‐hold‐slide tests were conducted to measure the steady‐state coefficient of friction, velocity dependence and healing between temperatures of 98 and 248 K at a normal stress of 100 kPa. Rate‐state friction parameters determined from velocity steps provide stability values. The friction results are used to infer fault strength and frictional heating of an icy crust with depth for both a pure ice crust and one containing ammonia. We find a reduced coefficient of friction for an ammonia‐bearing crust and stronger velocity dependence in the presence of partial melt. The temperature dependence of fault stability maps a seismogenic zone with depth analogous to the synoptic model for terrestrial fault stability, where we find instability between 0.7 and 3.9 km with a return to stability from 4.6 km if we assume a 6 km ice shell. We consider the role of sliding velocity and fault thickness on localized frictional heating in both systems and estimate the depth of melt generation in an ammonia‐bearing crust. Our results imply that faults at conditions similar to icy satellites can be seismogenic.

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