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Where is this?

Where is this?. 11 hour movie. Solar System Explorers. NONE THIS WEEK CONCENTRATE ON PAPER OUTLINE. Research Paper Level 1. due Thursday, 20 SEP outline of your research project (worth 10 points ) the more original, the better print out and hand in (Latex format)

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Where is this?

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  1. Where is this? 11 hour movie

  2. Solar System Explorers NONE THIS WEEK CONCENTRATE ON PAPER OUTLINE

  3. Research Paper Level 1 due Thursday, 20 SEP outline of your research project (worth 10 points) the more original, the better print out and hand in (Latex format) 10 pieces required: 1. Abstract (2+ sentences) 2. Introduction (2+ sentences … why do we care?) 3. Motivation (2+ sentences … why do YOU care?) 4. Sections listed (sample, observations, data, reductions …) 5. Discussion (2+ sentences) 6. at least 2 Tables listed 7. at least 2 Figures listed 8/9/10. three REFEREED references

  4. Planetary Atmospheres I art by Alan Gutierrez

  5. Planetary Atmospheres I heated/energized from above by Sun photochemistry heated/energized from below by the planet volcanism internal heat greenhouse effect clouds winds storms … various effects on surface evolution

  6. Overview all planets + 7 dwarfs + Pluto have them (8 for real; 8 are wimpy) Terrestrial thin skins (200 km thick, or < 5% R) Gas Giants enormous (~ 20% R at Jup, ~ 45% R at Sat) Ice Giants moderate (~ 30% R) note: T at base of atm = 6800K (J), 6100K (S), 2500K (U/N)

  7. Scale Height using hydrostatic equilibrium and ideal gas law: dP = – g(z)ρ(z)dz P = ρ R T / μ = ρ k T / μ m find the atmospheric pressure as a function of altitude: P(z) = Po e – ∫ dz/HP(z) with the pressure scale height given by HP(z) = kT(z) / g(z) μ m where μ = mean molecular weight (in amu) m = 1.67 x 10-24 g (one amu) so, pressure drops by factor of e in one scale height turns out to be the ~same for all substantial atmospheres: 10–50 km …because T, g, and μ balance (at least in Jovian atmospheres near P = 1 bar)

  8. 16 Atmospheres PLANETS OTHERS comp (> 1%) P (bar) H (km) comp (> 1%) P (bar) H (km) HP(z) = kT(z) / g(z) μ m

  9. Where is Earth’s Carbon? one way arrow units are Gigatonnes www.climatescience.gov/Library/stratplan2003/final/ccspstratplan2003-chap7.htm

  10. Sun

  11. Top 10 Differences Between Planetary and Stellar Atmospheres • Upper atmosphere heated by Sun. • Lower atmosphere heated by planet. • Volcanoes may add localized heating and chemical species. • Chemical reactions abundant at (generally) low T. • Clouds cause radical changes in opacity. • Phase transitions alter temp environment. • Crust and/or ocean will interact with atmosphere. • Weathering may change albedo. • Storms may alter pressure/temp structure in atmosphere. • Life may affect composition and energy balance.

  12. Generic Characteristics TROPOSPHERE convection sets temp temp drops with altitude clouds tend to form here STRATOSPHERE radiation (vs convection) temp increases with altitude MESOSPHERE radiation sets temp isothermal (or temp drop) portion of atmosphere mesopause forms second temp minimum on Earth + Titan THERMOSPHERE (IONOSPHERE) heating due to solar radiation UV 100−1000 Å photons blast e-, charged particles (aurorae) EXOSPHERE particles escape

  13. Earth THERMO (IONO): temp increase due to UV abs. ionization of O2 MESO: temp drop due to less O3 production, CO2 cooling STRATO: temp increase due to O3 production (abs. UV+IR) TROPO: weather clouds at tropopause

  14. Earth Greenhouse 6 greenhouse gases H2O CO2 CH4 N2O CFCs O3

  15. Earth vs. Venus Greenhouses

  16. Venus THERMO: 300 K vs 100 K day/night because CO2 very efficient radiator MESO: isothermal [ STRATO: there really isn’t one! ] TROPO: greenhouse due to CO2 heats diurnal/latitudinal/temporal temp variations less than 5K

  17. Venus vs. Earth : height

  18. Venus vs. Earth : pressure

  19. Mars

  20. Mars THERMO: low, uniform temp due to CO2 as efficient radiator and rapid rotation MESO: thick isothermal layer [ STRATO: there really isn’t one! ] TROPO: T swings from 200K-300K eccentricity changes temp by 30K dust typically heats by 10K CO2 cold-trapping changes P X

  21. Mars vs. Earth : height X

  22. Mars vs. Earth : pressure X

  23. Titan

  24. Titan MESO/THERMO: hydrocarbon cooling, (HCN) so T drops STRATO: up to 177K TROPO: clouds … and rain? similar overall atm structure to Earth although deeper

  25. Titan vs. Earth : height

  26. Titan vs. Earth : pressure

  27. Terrestrial Atmospheres note temperature structures --- Earth’s O3 causes stratosphere pressure scale height: HP(z) = kT(z) / g(z) μ m μ = mean molecular weight (in amu) m = 1.67 x 10-24 g (one amu) Venus Earth Mars Titan Hsurf 16 km 8.5 11 20 P100 km 10-4 bar 10-6 10-8 10-2

  28. Atmospheric Composition SPECTROSCOPY line position … which gas? line shape … how much? T? P? moving? WHAT TO LOOK FOR, WHERE TO LOOK excitation/de-excitation typically in ultraviolet or visible vibration typically in infrared rotation typically in radio GO THERE! (GC)MS = (gas chromatograph) mass spectrograph Earth, Moon, Venus, Mars, Jupiter, Titan particularly good for He, Ne, Ar, N2

  29. Terrestrial Compositions Earth Venus Mars Titan at least 1% ppm

  30. Terrestrial Atm Highlights Earth O2 out of equilibrium + O3 blanket largest % atmospheric H2O in Solar System 6 greenhouse gases Venus ~100X Earth pressure SO2 from vulcanism Mars ~1% Earth pressure … wimpy O3 blanket, H2O content sublimation/condensation cycles dust Titan Earthlike structure and pressure hydrocarbons + nitriles

  31. …………………………

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