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ASTRONOMY 340 FALL 2007 2 October 2007 Class #9. Salient Martian Features  R Mars = 3396 km (R Earth = 6378 km)  Higher surface area to mass ratio 

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Presentation on theme: "ASTRONOMY 340 FALL 2007 2 October 2007 Class #9. Salient Martian Features  R Mars = 3396 km (R Earth = 6378 km)  Higher surface area to mass ratio "— Presentation transcript:

1 ASTRONOMY 340 FALL 2007 2 October 2007 Class #9

2 Salient Martian Features  R Mars = 3396 km (R Earth = 6378 km)  Higher surface area to mass ratio  More efficient cooling  Lower internal heat flow, less volcanism  No plate tectonics  Atmospheric Composition  95% CO 2 (same as Venus)  Pressure = 0.006 bar (Earth = 1, Venus = 89)  T Surface  hey, it’s cold!  Mean solar constant  0.431 (Earth =1)  Summer  T ~ 273K (max)  Winter (polar)  T ~ 150K  ground is permanently frozen to 1 km

3 Soil Composition

4 Mars Missions  Current Missions  Spirit and Opportunity (rovers)  2001 Mars Odyssey (orbiter)  Mars Global Surveyot (orbiter)  Mars Express (polar orbit)  Mars Reconnaissance Orbiter (just launched)  Planned  Phoenix  Mars Science Laboratory  Past  Mariner flybys/orbiters  Viking landers  Pathfinder

5 NASA Mars Missions -- Goals  Determine whether life ever arose on Mars  Characterize the Climate of Mars  Characterize the Geology of Mars  Prepare for Human Exploration

6 Where to land?  Equatorial  maximum solar radiation  Low elevation  maximum atmosphere to slow descent, low shear  Relatively flat to preserve airbag  Radar-reflective, hard surface for rovers

7 Where to land?  Parachute to slow descent, followed by bouncing airbag….

8 Gusev Crater

9 Spirit Landing Site Golombek et al 2005 Nature 436 44  Nice and flat….

10 Opportunity landing site – and some space junk

11 Rock size distribution on landing sites

12 Surface Composition Bibring et al. 2005 Science 307 1576  Ices/Frosts  CO 2 veneers over polar ice caps  H 2 O ice w/ dust  Hydrated Minerals/Ferric Oxides  Significant presence – detected via 3 μ m feature  Primarily in older craters (younger craters lack hydrated minerals)  Igneous Rocks  Standard olivines

13 Water on Mars  Canals?  Background  origin of H 2 O on Earth  Outgassing via internal processes  volcanic Formation via accretion of hydrated protoplanetary material  External origin via hydrated impactors (comets?)  Maintaining liquid H 2 O on surface….  Temperature Liquid H 2 O unstable at 150 K < T < 220 K But ice on stable at poles  Pressure Sublimation of polar ice  atmospheric pressure insufficient to maintain water in atmosphere Dissociation of H 2 O, loss of H  Current conditions not favorable for liquid H 2 O on Martian surface or significant H 2 O in atmospere  But…..

14 Water on Mars  Polar Ice Caps  Mariner 9 (1972)  images of obvious channels that look like river beds  major amounts of surface water in past  Atmospheric chemistry  Trace H 2 O content via outgassed volatiles  80-160m of water outgassed North Polar Ice Cap in summer

15 Water on Mars  Water channels  Outflow channels Catastrophic floods (10 8 m 3 s -1 vs 10 4 m 3 s -1 ) “sudden” appearance Volcanism, internal pressure, ???  Valley networks Look like river systems groundwater  Fretted channels  Remote sensing/imaging

16

17 Possible water flow as seen by Global Surveyor.

18 Gusev Crater Haskin et al 2005 Nature 436 66  Gusev plain  an old lake bed?  Primarily igneous rock (olivine basalt)  Veins/plugs  aqeous solutions plausible  Composition measured via near-IR spectrometer

19 Gusev crater Haskin et al 2005 Note inclusions – need water to form

20 Gusev Crater Haskin et al 2005 Nature 436 66  Veins/plugs  aqeous solutions plausible  Composition measured via near-IR spectrometer  Various geochemical effects of aqeous solutions E.g. ratio of Al 2 O 3 vs SO 3 Increased ratio of salts, oxidation of Fe 2+  Conclusions: running water, but no pools/oceans Inverse correlation – mixing with evaporative component with high S content

21 Gusev Crater Haskin et al 2005 Nature 436 66  Gusev plain  an old lake bed?  Primarily igneous rock (olivine basalt)  Veins/plugs  aqeous solutions plausible  Composition measured via near-IR spectrometer  Various geochemical effects of aqeous solutions E.g. ratio of Al 2 O 3 vs SO 3 Increased ratio of salts, oxidation of Fe 2+  Conclusions: running water, but no pools/oceans

22 Frozen Equatorial Sea? Murray et al. 2005 Nature 434 352  What are these cracked “plates”? Lava? The authors think not…  Edges much younger than rest of plate – lava doesn’t do this  Crater density suggests age ~ 5Myr  Resemblance of plates to pack-ice in Arctic

23 a. Mars 13.7m resolution b. Antarctica c. Martian ice raft?

24 But is there water there now? Diagram showing possible fossil water flow from subsurface source. Images from Global Surveyor. See handout.

25 Phobos & Deimos  Low inclination, equatorial orbits

26

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