1 / 14

Prometheus Lava-Frost Interaction

Prometheus Lava-Frost Interaction. Robert R. Howell University of Wyoming. Overview. SO 2 gas generation rates HST SO 2 column density (Jessup et al. 2004) plus numerical plume dynamics (Zhang et al. 2004) plume dynamics Confirms updated ~10 4 kg/s from Ingersoll type models

morela
Download Presentation

Prometheus Lava-Frost Interaction

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Prometheus Lava-Frost Interaction Robert R. Howell University of Wyoming

  2. Overview • SO2 gas generation rates • HST SO2 column density (Jessup et al. 2004) plusnumerical plume dynamics (Zhang et al. 2004) plume dynamics • Confirms updated ~104 kg/s from Ingersoll type models • SO2 erosion rates (m/s as function of time) • From modified lava-flow model or simple energetics • Integration of rates over various age flows • Also modified from lava flow model • Combine above with Galileo SSI 5 m2/s lava on frost spreading rate (Milazzo et al. 2001) to get • Constraints on frost or lava thickness • Comparison of IR and gas power (GW)

  3. Original Calculation – Ingersoll model • Presented in Jessup et al. (2004) with correction in Lellouch et al. (2006) (Jupiter book) • Analytical model where excess pressure (above vapor pressure) drives excess collisions with surface. • Psurface (or column density), T  collision rate with surface (per unit area per unit time). •  (Sticking coef.), Pvapor  excess collision rate (above equil.) • Excess rate  area of plume  kg/s Updated geometry from Geissler? • Updated value 104 kg/s of SO2

  4. Zhang et al Cross-Section of Plume density • Numerical model follows expansion and condensation of gas (and small plume particles which follow gas) • Shape of plume constrained by Voyager on-the-limb brightness contours (which sense dust). • Model assumes gas characteristics at vent – but are not well constrained by Voyager observations since dust/gas ratio isn’t very certain. Density of gas in plume proportional to assumed vent density. • Can use HST SO2 column density to constrain Zhang model and therefore obtain “independent” estimate of SO2 generation rate.

  5. Zhang et al. 2004 Prometheus SO2density profile • Zhang et al. (2004) SO2 number density normalized to 51016 m-3. • Assumes vent conditions equivalent to 1.6 103 kg/s but poorly constrained

  6. Column density derived from density profile • Column density falls rapidly beyond 15 km radius, with long tail • HST observations have ~300 km spatial resolution (i.e. ~150 km radius) • Horizontal line represents HST value and spatial resolution • Ratio of observed to averaged model is ~5 (so assumed vent gas density too low) • Supply rate = 5 x 1.6 103 kg/s = 8.0103, close to “Ingersoll model” 104 kg/s

  7. Lava – Frost interaction overview • Assume lava crust in contact with frost (or perhaps liquid) SO2 • Assume lava maintains coherent crust • Same assumption as in Milazzo et al. 2001 • Ignores possibility of violent mixing • Calculate heat out of lava flow using modified “flow model” • Assume all that heat is used to vaporize SO2 • So vaporization rate  heat flow / (latent heat of sublimation) • Vaporization rate will vary with time as lava crust thickens and heat flow drops • Mathematics for averaging vaporization rate over different age flows is exactly analogous to mathematics for averaging infrared emission • Final results different because different power laws involved in rates

  8. Heat flow from lava flow • Published Howell (1997) model uses “Stefan solution” to find heat flow and temperature from cooling and solidifying lava flow. • Stefan solution is “exact” if surface of lava is clamped at some T0 • Gives heat flow q(t) through surface, plus interior temperature of lava crust • Flow model makes initial estimate of T0 then uses it to calculate q(t) • Then uses q(t) and radiate boundary condition to refine estimate of surface T(t) • Approximations are even better for lava crust quenched by contact with frost • Only requires minor modification of initial T0 guess (or T Tmelt-T0) • Use T0  198K = triple point temperature of SO2 so T  1200 K • Lava flow model assumed T0 ~ 400K so T  1000 K • Insensitive to exact temperature of boundary since that has little effect on T.

  9. Erosion rates from heat flow • SO2 mass flux from surface (Fm) has similar functional form • Velocity of vaporization wave is just Fm/frost • Integrate velocity to get erosion depth of SO2

  10. Others’ erosion rates • Difference from Milazzo et al. 2001 estimate • This work: • Milazzo et al 200184.4 times less • Factor of 2 could be material constants, rest unexplained • Test of model with Kieffer et al. 2000 estimate • “Back-of-the-envelope” calculation of thickness of silicate crust, then heat flux through it gives erosion rate after 200 minutes of 6.410-5 m/s • Previous page’s eqn gives 6.110-5 m/s, in very good agreement

  11. Averaging over different ages • Equations analogous to spectral average • Assume new flow created at constant areal rate Ra • Assume flow started time ta ago, ended time tb ago • tb =0 for ongoing flow

  12. Implications of SO2 and flow rate known • Milazzo et al. 2001 using I24 vs. I27 images measured RA=5m2/s of new dark flow over bright (SO2) areas • Substitution into previous equation gives tA ~ 1 day. • If flow continued for months, what else could cut off vaporization after one day? • Depth of SO2 snow field • 4 meters eroded after one day • Solidification then cooling of lava • 0.5 meters solid after one day – but cooling would continue vaporization • Energetics of cooling imply 0.2m lava depth will work • More complicated geometries • Lava burrows under SO2 (but should still vaporize snow above by radiation) • Other more complicated geometries?

  13. Comparison of Powers from IR, Vaporization • 104 kg/s vaporization requires 5 GW • Observed infrared power 100-150 GW • Factor of 20-30 difference simply implies that only 1/20 or 1/30 of newly created lava flows interact with SO2. • The rest are presumably new lava flows on top of “dry” slightly older flows

  14. Summary • Gas rate 104 kg/s confirmed (if geometry OK) • Adapted lava flow models show how SO2 rate depends upon material constants, areal rate, and time parameters • If 5 m2/s rate and 104 rate are right, something cuts off vaporization after 1 day • 4 meter depth of snow field? • 0.2 meter depth of lava? • More complicated geometry?

More Related