Completed
Potential Recharge of Subpermafrost Groundwater by Polar Basal Melting
Class Central Classrooms beta
YouTube videos curated by Class Central.
Classroom Contents
The Climatic and Hydrologic Evolution of Water on Mars
Automatically move to the next video in the Classroom when playback concludes
- 1 Intro
- 2 Why We Care About Water On Mars
- 3 Estimated Martian Inventory of H2O
- 4 Martian Global Inventory of H2O: -0.5 - 1 km GEL, 2 -3.5 Ga (Carr, 1986)
- 5 Early Mars: Warm or Cold?
- 6 Potential Evolution of the Martian Hydrosphere
- 7 Mars Thermal History Model: Mantle Heat Flow vs. Time 400
- 8 Nature of the Martian Crust
- 9 Gravitationally-Scaled, Globally-Averaged Porosity & Permeability Profiles for Mars
- 10 Crater with Fluidized Ejecta: Potential Indicators of Impacts into a Water-or Ice-Rich Crust
- 11 Inferred hydraulic conditions by Late Hesperian, implied by elevation of outflow channel source regions: North
- 12 Hydraulic conditions during Late Hesperian
- 13 Inferred hydraulic conditions during the Noachian 3.8 Gya after the onset of a colder climate
- 14 Geomorphic Identification of Potential Paleoshorelines in the Martian Northern Plains (Parker et al., 1987, 1989, 1993; Clifford and Parker, 2001; Parker et al., 2010)
- 15 Distribution of Valley Networks Most Readily Explained by the Existence of a Martian Northern Ocean (Soto et al., 2010)
- 16 Instability of ice at low-latitudes leads to sublimation and cold-trapping at the poles
- 17 Potential Recharge of Subpermafrost Groundwater by Polar Basal Melting
- 18 Geomorphic Evidence of Hesperian-Age Polar Basal Melting: Eskers, Valleys and the Chryse Trough Drainage System
- 19 Ocean freezes and cryosphere thickens, permitting rise of global water table