Physics
Scientific paper
May 2009
adsabs.harvard.edu/cgi-bin/nph-data_query?bibcode=2009georl..3610306b&link_type=abstract
Geophysical Research Letters, Volume 36, Issue 10, CiteID L10306
Physics
7
Geodesy And Gravity: Earth'S Interior: Dynamics (1507, 7207, 7208, 8115, 8120), Tectonophysics: Dynamics: Convection Currents, And Mantle Plumes, Mineral Physics: Equations Of State
Scientific paper
Using a numerical model we explore the consequences of the intrinsic density change (Δρ/ρ ≈ 2-4%) caused by the Fe2+ spin transition in ferropericlase on the style and vigor of mantle convection. The effective Clapeyron slope of the transition from high to low spin is strongly positive in pressure-temperature space and broadens with high temperature. This introduces a net spin-state driving density difference for both upwellings and downwellings. In 2-D cylindrical geometry spin-buoyancy dominantly enhances the positive thermal buoyancy of plumes. Although the additional buoyancy does not fundamentally alter large-scale dynamics, the Nusselt number increases by 5-10%, and vertical velocities by 10-40% in the lower mantle. Advective heat transport is more effective and temperatures in the core-mantle boundary region are reduced by up to 12%. Our findings are relevant to the stability of lowermost mantle structures.
Bower Dan J.
Gurnis Michael
Jackson Jennifer M.
Sturhahn Wolfgang
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