Quantitative geomorphology of the Mars Eberswalde delta

The Eberswalde delta is composed of six separate depositional lobes that have prograded some 17 km from their apex. Crosscutting distributary relationships and compensated depositional lobes are clearly visible in images acquired by the Mars Global Surveyor Mars Orbiter Camera. Here, several lobe systems have been examined for sinuosity, radius of channel curvature, meander-bend width, and channel width parameters. Channel sinuosities of between 1.2 and 1.8 defi ne low- to moderate-sinuosity systems typical of the type transporting bedload or mixed grain-size loads. Channel systems increase in sinuosity as they get older. However, some of the younger systems show specifi c reaches of increased sinuosity. These localized changes may be due to either abutment against resistant beds of older lobes or rise in base level at the channel system terminus. If the former, such an effect of older deposits on the morphology of the channels suggests that these older lobes were fairly well indurated prior to the deposition of the youngest progradational lobes. Eighty-six percent of distributaries in the Mars Eberswalde delta are 100‐240 m wide. Comparatively, 62% and 44% of distributaries in the Atchafalaya and Wax Lake deltas of Louisiana, respectively, are of similar size. Small distributaries may indicate lower average and shorter duration fl ows or coarser sediment in Mars distributaries than those typical of the Gulf Coast systems. The volume of the material in the Mars deposit suggests long periods of sediment deposition. Sinuosity indexes, meander-bend migration, and ridge-and-swale point-bar topography suggest periods of stable discharge on the delta surface.

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