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Astronomy 340 Fall 2005. 27 September 2005 Class #7. 90 Minutes Doing Your Homework. Review. CO molecule – Rayleigh-Jeans approximation substitute temperature for intensity in radiative transfer eqn. T b = ( λ 2 /2k)B λ T b (s) = T b (0)e - τ (s) +T(1-e - τ (s) ) Planetary Surfaces
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Astronomy 340Fall 2005 27 September 2005 Class #7
Review • CO molecule – Rayleigh-Jeans approximation substitute temperature for intensity in radiative transfer eqn. • Tb = (λ2/2k)Bλ • Tb(s) = Tb(0)e-τ(s)+T(1-e-τ(s)) • Planetary Surfaces • Processes at work: impact, weathering, atmosphere, geology (tectonics/volcanic • Mercury: heavily cratered, no tectonics • Venus: global resurfacing 300 Myr ago, no tectonics • Mars: water, older volcanoes • Earth: tectonics, water, weather
Surface Composition • Reflection spectroscopy derivation on board. • What is the surface made of? Rocks, mostly igneous • Minerals = solid chemical compounds with specific atomic structure
Common Minerals • Silicates • Si is produced via He-burning in stellar interiors, released via SNe. • O is produced in massive and intermediate mass stars • Si, O bind easily SiO4, SiO3 bind with lots of other things (Mg, Al, Fe) and form a solid at high temperature • SiO2 = quartz • (Fe,Mg)2SiO4 = olivine (most common) • CaAl2Si2O8 = feldspar 60% of surface rocks on Earth • Various Oxides • Fe2O3 = hematite generally formed from a reaction between Fe, O, and H2O has been found in Martian samples
Common Minerals • Silicon • 3rd most abundant element (after O, Fe) • Cosmically as abundant as Fe, Mg • Less abundant than C,N,O • Chemically between metals and non-metals • Can survive as solid in interstellar/circumstellar environment
Common Minerals • Silicon • 3rd most abundant element (after O, Fe) • Cosmically as abundant as Fe, Mg • Less abundant than C,N,O • Chemically between metals and non-metals • Can survive as solid in interstellar/circumstellar environment • Silicates • “lithophiles” = silicates and things that tend to attach themselves to silicates low density minerals, reside in the crust
Common Minerals • Silicon • 3rd most abundant element (after O, Fe) • Cosmically as abundant as Fe, Mg • Less abundant than C,N,O • Chemically between metals and non-metals • Can survive as solid in interstellar/circumstellar environment • Silicates • “lithophiles” = silicates and things that tend to attach themselves to silicates low density minerals, reside in the crust • Igneous rocks • 40-75% SiO2 • O:Si ratio is high at high temperature crystallization and you get more olivine; low at low T and you get more quartz
Common Minerals • Silicon • 3rd most abundant element (after O, Fe) • Cosmically as abundant as Fe, Mg • Less abundant than C,N,O • Chemically between metals and non-metals • Can survive as solid in interstellar/circumstellar environment • Silicates • “lithophiles” = silicates and things that tend to attach themselves to silicates low density minerals, reside in the crust • Igneous rocks • 40-75% SiO2 • O:Si ratio is high at high temperature crystallization and you get more olivine; low at low T and you get more quartz • Differentiation absence of “siderophiles” in crust is evidence of differentiation
Tectonics What Separates the Earth from Others • Convection means of transporting heat driven by internal heat (radioactive decay?) • Crustal plates are cold upper lid on convective cells “subsolidus” convection in mantle (3000 km thick) • Consequences • Volcanic activity, mountain chains • Mid-ocean ridges • Continental drift, earthquakes
Tectonics • 1st evidence mapping magnetic field in Indian Ocean floor detection of distinct linear features interpreted as “sea-floor spreading” • Puzzle-piece like nature of continents • Youngest rocks near mid-ocean ridges
Dating: Radionuclide Chronometry • Processes ( Most Important Cases) • 40K 40Ar t½ = 1.4 x 109 yrs • 87Rb 87Sr t½ = 6 x1010 yrs • 238 U 206 Pb t½ = 5 x 109 yrs • Lunar Results • Oldest Highland Anorthosite tsolid. = 4.2 x 109 yrs • Youngest Mare Basalts tsolid. = 3.1 x 109 yrs • Terrestrial Results
Radioactive Decay • Consider a number density, n, of atoms • Which decays at an average rate, l • The solution to which is: • Now n = ½ n0 at time t = t1/2 so • Or, • And finally:
Venus’ Tectonic Activity?Smrekar & Stefan 1997 Science 277, 1289 • Venus’ past • Crater distribution is even & young no resurfacing over past 300-500 Myr (Price & Supper 1994 Nature 372 756) • No global ridge system and a lack of significant upwellings (Solomon et al. Science 252 297) • Why such a big difference compared with Earth? • Catastrophic loss of H2O from mantle? no convection • “coronae” are unique to Venus • rising plumes of magma exert pressure on lithosphere • less dense lithosphere deforms under pressure • deformation of crust without tectonics
Martian Tectonic ActivityConnerney et al ’99 Science 284 794 • Mars Global Surveyor • Detected E-W linear magnetization in southern highlands • “quasi-parallel linear features with alternating polarity” • Note: Earth’s global B-field is so much stronger it makes crustal sources hard to detect
Martian Tectonic ActivityConnerney et al ’99 Science 284 794 • Mars Global Surveyor • Detected E-W linear magnetization in southern highlands • “quasi-parallel linear features with alternating polarity” • Note: Earth’s global B-field is so much stronger it makes crustal sources hard to detect • Mars has no global field so crustal field must be remnant (“frozen in time”) from crystallization
Martian Crustal Magnetization • Working model • Collection of strips 200 km wide, 30 km deep • Variation in polarization every few 100 km • 3-5 reversals every 106 years (like seafloor spreading on Earth) • Some evidence for plate tectonics…but crust is rigid • Earth’s crust appears to be the only one that participates in convection
