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Influences of Compositional Stratification

Learn the impact of compositional stratification on planetary evolution, thermal convection, and viscosity. Discover how density variations due to composition affect planetary mantles. Be introduced to 2D numerical experiments on stable stratification.

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Influences of Compositional Stratification

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  1. Influences of Compositional Stratification S.E.Zaranek E.M. Parmentier Brown University Department of Geological Sciences

  2. Influences of Compositional Stratification • Effect on Buoyancy • a. * Stable Stratification and Thermal Convection • b. Unstable Stratification driving Convection • * Effect on Viscosity • Effect on Distribution of Heat-producing • (Radiogenic) Elements * focused on in this talk

  3. Compositional Stratification Compositional Stratifications (e.g. core & the mantle) are well recognized as having a major influence on planetary structure. Density variations due to composition in planetary silicate mantles can be large compared to those temperature difference available to drive thermal convection. Some cause of compositional stratifications of the mantle are Crystallization and Overturn of a Magma Ocean Partial melting such as in the genesis of crust

  4. Convection in Presence of Stable Compositional Stratification Density variations due to composition in planetary silicate mantles can play a significant role in their thermal evolution. Temperature-dependent viscosity restricts the temperature difference (available buoyancy) that drives convection and therefore increases the effect of compositional stratification. The onset of thermally driven convection is delayed or suppressed and the depth scales of convective motions are restricted. Can predict behaviors with simple scaling laws and parameterizations. May be important in the thermal evolution of the oceanic upper mantle, formation of subcratonic continental lithosphere, and for planetary evolution, more generally.

  5. 2D Numerical Experiments Thermal Convection w/ Initially Stable Compositional Stratification Formulated with 2nd order finite difference approximations on a staggered grid Multigrid iterative flow solver Smolarkiewicz method for advection Initially stable linear density gradient Cooling from above, No volumetric heating Temperature dependent rheology using exponential law ¶ c + × = u c 0 Ñ ¶ t ¶ T + × Ñ = k Ñ 2 u T T ¶ t ( ) - Ñ + Ñ × m Ñ + Ñ + r = p ( u ' u ) g 0 r = r + b + a ( 1 c T ) o Important nondimensional parameters: Rabox = ρoαDTigL3/μiκ γ = 1/ρo dρ/dz Ñ × = u 0

  6. Temperature Dependent Viscosity • In a fluid with a strongly temperature dependent viscosity: • Convection is confined to a hot, low viscosity region beneath a conducting lid (thickness,dL). • Convecting thermal boundary layer (thickness,dc) is present between the conducting lid and the isothermal interior. • The temperature difference across the convecting thermal boundary layer denoted as DTc and corresponds to a viscosity increase of ~10. Temperature Contours

  7. Convective Regimes 1) Convective Overturn Leading to Formation of a Mixed Layer that Thickens with Time 2) Formation of a Mixed Layer that does not Thicken with time 3) Oscillatory Convection where Heat is Transferred Faster than Conduction alone but with Little or No Mixing 4) No Convection. Horizontally Averaged Contours Of Composition

  8. Characteristics of Convection in Stably Stratified Fluids • Interested in Characterizing: • Onset Time of Convection • Initial Downwelling Depth • Growth rate of the Mixed Layer • Maximum Depth of Mixing • 5. Reduction of Surface Heat Flux Blue-less compositionally dense material, colder material Red- more compositionally dense material, hotter material

  9. Onset Time of Convection gd c a D T c r a d m gd a D T ( T g / ) F ( / ) D T = gd a D = o c c i c c Ra F ( / ) Ra d D T , c c crit k d 2 / c c Solve for F(gdc/aDTc) using the RT growthrates from linearized analysis and compare with results from 2D Numerical Experiments Important Ratio increasing onset time increasing relative stratification

  10. Stability Criteria for Convection - 3 2 æ ö r a D a D g d gd 3 æ ö ( T g )( T / ) ç ÷ = = ç ÷ o c c c Ra Ra ç ÷ g d D c , Tc m k d a D T è ø è ø c i c For a given value of activation energy (determines DTc, dc/d) and compositional gradient (g), the value of Rag remains constant as the thermal boundary layer grows.

  11. Formulation of Scaling Laws Schematic of the Idealization of a Well-mixed Layer To derive scaling laws: 1. Composition: Average of the initial over the mixed layer depth. Temperature: Uniform value Tm outside thin thermal boundary layers at the top and bottom. 2. Beneath the mixed layer, temperature and composition retain their initial values. 3. Density continuity (buoyant rather than viscous entrainment) at the interface between the mixed and unmixed layers 4. Conservation of heat 5. Parameterized convective heat flux (e.g. Davaille and Jaupart, 1993) at the base of the conductive lid

  12. Thickening of the Mixed Layer The mixed layer thickens by the penetration of plumes into the still stratified layer. 4 / 3 1 / 3 æ ö æ ö æ ö - ra D a D g 2 d ( z z ) T g T z mixed ç ÷ ç ÷ ç ÷ = k - c L c c mixed 1 ç ÷ ç ÷ ç ÷ m k g a dt ( T ) 2 T è ø è ø è ø m i For planetary scales, thickening rate ~5-25k

  13. Application to Subcratonic Lithospheric Evolution

  14. Application to Subcratonic Lithospheric Evolution Can the Lithosphere Experience an Oscillatory Mode of Convection? * Rag = ~ 2.5 x105 – 6.5 x 106 (mi=1017 Pa s) * Rag= ~ 2.5 x 104 – 6.5 x 105 (mi=1018 Pa s) Forg = 5-8 x 10-3 % per km Q = 300-520 kJ/mol Yes – trade off between Q and mi, but possible

  15. Compositional Viscous Lid from Hirth et al, 2000 (from electrical conductivity profiles) from Lee et al., 2004

  16. 1 / 3 æ ö ra g ç ÷ 4 / 3 = D f c k T ç ÷ convect 1 c m k è ø min = f f convect conduct Influence of Compositional Viscous Lid

  17. Influence of A Viscous Compositional Lid Ratio ~ 1.09-1.2 175 km compositional lid thickness at maximum yields thermal thickness of 210 km

  18. Conclusions Compositional Stratification may significantly alter convection by affecting the buoyancy forces, the viscosity structure and the distribution of radioactive elements. Buoyancy: With a stable compositional stratification, the onset of thermally driven convection is delayed or suppressed and the depth scales of convective motions are restricted. Convective behavior can be predicted and parameterized, where one of the key ratios is aDTc/gdc. Predicted stratifications for subcratonic lithosphere is significant enough to strongly influence the convective behavior. Oscillatory style convection is possible.

  19. Conclusions Compositional Stratification may significantly alter convection by affecting the buoyancy forces, the viscosity structure and the distribution of radioactive elements. Viscosity: Compositional stratification may also be accompanied by viscosity stratification (dehydration?) A compositionally viscous lid can either be too thin to effect convection (still within the conductive/stagnant lid of temp- dep viscosity) or thick enough to define a new stagnant lid. A near constant ratio of thermal thickness to composition thickness for specific values of Q, V, and mref. This ratio ranges from 1.09-1.2, indicating (at maximum) a 175 km compositional viscous lid would produce a thermal thickness of 210 km.

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