Mars

1. Mars ASTR-3040 Astrobiology Day 19

2. Homework • Chapter 8 • Due Thurs. March 31 • 3, 7, 13, 23, 30, 32, 41, 46, 51, 52 • Plus (49 or 50) if you've read one of the books or seen one of the movies.

3. Search for Life on Mars • Evidence – 3 categories • 1. Viking experiments • 2. Methane in atmosphere • 3. Martian meteorites found on Earth

4. Viking • Carbon Assimilation Experiment. • Mix soil with CO, CO2, H2O (tagged) to see if incorporated into the soil – would indicate life. • No positive result. • Gas Exchange Experiment • Mix soil with organic broth and look for gas release • No positive result.

5. Viking • Labeled Release Experiment • Mix soil with organic broth and look for gas release. • Should increase if life was present. • Positive result, and heating stopped it. • Gas Chromatograph/Mass Spectrometer • Look for organic molecules in soil. • No positive result, and sensitivity seems to rule out the results of the LRE.

6. Viking • Methane on Mars • Mars Express found significant level of methane in atmosphere, cyclic concentration levels. • Comet impacts, volcanoes, or life. • Potential correlation with water vapor location. • But, could be outgassing from volcanic activity. • If warm enough to support this, could also be warm enough to support liquid water underground.

7. How do we Search for Life? • Mars Reconnaissance Orbiter (2006)‏ • Higher resolution images to map landing sites. • Phoenix (2008) lander to look for ice near poles • and organic material. • Next up: • Mars Science Laboratory (2009 launch) • More sophisticated rovers than Spirit & Opportunity • Sample return mission about 2014 - 2016.

8. Contamination • Real concern • 1967 treaty requires < 1:1000 chance • Strive to do better than this. • Spacecraft sterilization program. • Sample return mission has a reverse concern. • Think “Andromeda Strain” • Do we use ISS as the quarantine facility?

9. Humans • Long term goal (2025-2030?)‏ • Shielding is a concern for radiation hazard. • Vast amount of stuff needed for a long mission. • Pro: • Humans can explore better than robots. • Real time decisions, autonomous. • Con: • Serious contamination issue.

10. Terraforming • Long, expensive process • How increase greenhouse gas concentration? • How increase atmospheric pressure? • How maintain the new atmosphere? • Liquid water? • Ethical issues

11. Martian Meteorites • 1984 - “Allen Hills” region of Antarctica ALH84001 • 1996 - “fossil evidence” for life on Mars. • Igneous, about 4.5 Gyr old. • Probably on surface when water was present. • Carbonate grains in the rock – 3.9 Gyr old • Formed in water. • Blasted off of Mars about 16 Myrs ago and landed on Earth about 13,000 yrs ago.

13. Evidence for Life • Carbonate grains – Mg-, Fe-, Ca-rich carbonates • layering caused by life on Earth • PAHs in the carbonate grains • Much higher in ALH84001 than in other meteorites • Produced by decay of dead organisms. • Magnetite crystals in Fe-rich layers of carbonates • On earth, only produced by bacteria • High magnification images show rod-like structures • Nanobacteria? Found on Earth now.

14. Microscopic chains of magnetite crystals. Top: Earth bacteria; Bottom: ALH84001 Top: Terrestrial nanobacteria from Sicily. Bottom: ALH84001 structures, 100 nm long

15. Alternate Explanations • Carbonate grains • Pulses of hot water might produce this structure. • PAHs in the carbonate grains • Terrestrial contamination in Antarctica • Magnetite crystals in Fe-rich layers of carbonates • Coincidental? Theoretical ways to form them • Not shown experimentally • High magnification images show rod-like structures • They just look like nanobacteria. • They might be an artifact of slicing the rocks

16. Summary • We don't really know. • Probably will have to wait until we can actually study rock in situ and bring some back for more detailed analysis.