Incorporating Density Properties of MgSO4 Brines Into Icy World Ocean Simulations

Details Incorporating Density Properties of MgSO4 Brines Into Icy World Ocean Simulations Incorporating Density Properties of MgSO4 Brines Into Icy World Ocean Simulations

Dec 2011

adsabs.harvard.edu/cgi-bin/nph-data_query?bibcode=2011agufm.p22b..05g&link_type=abstract

American Geophysical Union, Fall Meeting 2011, abstract #P22B-05

Biology

[4534] Oceanography: Physical / Hydrodynamic Modeling, [5220] Planetary Sciences: Astrobiology / Hydrothermal Systems And Weathering On Other Planets, [5460] Planetary Sciences: Solid Surface Planets / Physical Properties Of Materials, [6221] Planetary Sciences: Solar System Objects / Europa

Scientific paper

The structure and flow of the subsurface oceans in icy worlds depends on the sources of buoyancy within these oceans. Buoyancy is determined by the equation of state, in which density is a nonlinear function of temperature, salinity, and pressure. Equations of state for terrestrial seawater (with Na and Cl as the principal dissolved species) are well-developed, but icy world oceans may contain a different balance of species, including Na, Mg, SO4, and NH4 (Kargel et al, 2000). Recent work by Vance and Brown (2011, pers. comm.) has mapped out the density and thermodynamic properties of MgSO4 brines under icy world conditions. We have developed code to incorporate this equation of state data for MgSO4 brines into two different ocean simulation models. First, we investigate a single-column convection model, which is able to find the equilibrium structure and heat transport of an icy world ocean. We explore the heat transport through the ocean subject to a variety of assumptions about ocean salinity and seafloor heat and salt flux. We resolve the paradox posed by Vance and Brown (2004): warm salty MgSO4 brine emitted by a seafloor hydrothermal system may be positively buoyant at the seafloor, but become negatively buoyant (sinking) at lower pressure. How does heat escape the ocean, if it cannot be transported by convection? Second, we add MgSO4 dynamics to a full 3-D time-dependent general circulation model (the MIT GCM), which is able to simulate both the global-scale circulation of the world's ocean and investigate the highly turbulent dynamics of buoyant hydrothermal systems. We ask, "Are buoyancy-driven flows in a MgSO4 brine ocean significantly different than similarly-driven flows in terrestrial seawater?"

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