Details

Autor(en) / Beteiligte

• Grimm, Robert E.
• Harrison, Keith P.
• Stillman, David E.

Titel

Water budgets of martian recurring slope lineae

Ist Teil von

• Icarus (New York, N.Y. 1962), 2014-05, Vol.233, p.316-327

Ort / Verlag

Elsevier Inc

Erscheinungsjahr

2014

Quelle

Alma/SFX Local Collection

Beschreibungen/Notizen

• •Model water flows driven by gravity and capillary suction in a porous layer.•Fifty millimeter flow in sand under fine-grained overburden satisfies observations.•Source confinement to annual layer of ice melting requires discontinuous flow.•Recharge from buried ice, atmosphere, or aquifer. Flowing water, possibly brine, has been suggested to cause seasonally reappearing, incrementally growing, dark streaks on steep, warm slopes on Mars. We modeled these Recurring Slope Lineae (RSL) as isothermal water flows in thin surficial layers driven by gravity and capillary suction, with input from sources in the headwall and loss to evaporation. The principal observables are flow duration and length. At 40% porosity, we find that flow thicknesses reaching saturation can be just 50mm or so and freshwater RSL seasonally require 2–10m3 of H2O per m of source headwall. Modeled water budgets are larger for brines because they are active for a longer part of each day, but this could be partly offset by lower evaporation rates. Most of the discharged water is lost to evaporation even while RSL are actively lengthening. The derived water volumes, while small, exceed those that can be supplied by annual melting of near-surface ice (0.2–2m3/m for a 200-mm melt depth over 1–10m height). RSL either tap a liquid reservoir startlingly close to the surface, or the actual water budget is several times smaller. The latter is possible if water never fully saturates RSL along their length. Instead, they would advance like raindrops on a window, as intermittent slugs of water that overrun prior parts of the flow at residual saturation. Annual recharge by vapor cold trapping might then be supplied from the atmosphere or subsurface.