Course

1. Astronomy 101The Solar SystemTuesday, Thursday2:30-3:45 pmHasbrouck 20Tom Burbinetomburbine@astro.umass.edu

2. Course • Course Website: • http://blogs.umass.edu/astron101-tburbine/ • Textbook: • Pathways to Astronomy (2nd Edition) by Stephen Schneider and Thomas Arny. • You also will need a calculator.

3. Office Hours • Mine • Tuesday, Thursday - 1:15-2:15pm • Lederle Graduate Research Tower C 632 • Neil • Tuesday, Thursday - 11 am-noon • Lederle Graduate Research Tower B 619-O

4. Homework • We will use Spark • https://spark.oit.umass.edu/webct/logonDisplay.dowebct • Homework will be due approximately twice a week

5. Astronomy Information • Astronomy Help Desk • Mon-Thurs 7-9pm • Hasbrouck 205 • The Observatory should be open on clear Thursdays • Students should check the observatory website at: http://www.astro.umass.edu/~orchardhill for updated information • There's a map to the observatory on the website.

6. Final • Monday - 12/14 • 4:00 pm • Hasbrouck 20

7. HW #15 • Due next Tuesday

8. Exam #3 • This Thursday • Covers material from October 15th – November 5th • Bring pencil and a calculator • Review Session – Wed. at 6 pm in Hasbrouck 134 • Formulas (I also would not forget the formulas that I learned earlier) Density = mass/volume Volume = 4/3r3

9. HW Review

10. Mercury/Venus • Mercury is the closest planet to the Sun • Venus is next closest

11. Mercury • orbit: 0.38 AU from Sun • diameter: 4,880 km (38.3% of Earth) • mass: 3.30 x 1023 kg (5.5% of Earth) • temperature: 90 K (minimum) 440 K (average) 700 K (maximum) • Satellites: Zero

12. Difficult to study Mercury • Because of Mercury's proximity to the Sun • makes reaching it with spacecraft technically challenging • Earth-based observations difficult.

13. Mercury • Videos • http://www.gecdsb.on.ca/d&g/astro/html/Mercury.html

14. Mariner 10 • The only spacecraft to approach Mercury was NASA's Mariner 10 (1974-1975).

16. Caloris Basin

17. Caloris Basin(Some of the hill are 1,800 meters tall)

18. Messenger data Mariner 10 data

19. Caloris Basin • A basin was defined by Hartmann and Kuiper (1962) as a "large circular depression with distinctive concentric rings and radial lineaments." • Others consider any crater larger than 200 kilometers a basin. • The Caloris basin is 1,550 kilometers in diameter, and was probably caused by a projectile larger than 100 kilometers in size. • The impact produced concentric mountain rings three kilometers high and sent ejecta 600 to 800 kilometers across the planet.

22. Weird Terrain The weird terrain is almost opposite Caloris Basin. It consists of hills, ridges and grooves that cut across craters. The weird terrain my have been formed by shock waves that raced through the center of the planet and outward early in Mercury's history.

23. Mercury has high density • Its density is 5.44 g/cm3 which is comparable to Earth's 5.52g/cm3 density. • In an uncompressed state, Mercury's density is 5.5 g/cm3 where Earth's is only 4.0 g/cm3.

25. http://www.psrd.hawaii.edu/WebImg/MercuryCore.gif

26. Messenger • Mission to Mercury • Launched August 3, 2004 • Flew by Mercury in 2008 and 2009 • Will orbit Mercury in 2011

28. Messenger video • A set of five 11-band images was captured by MESSENGER just after the spacecraft crossed the night/day line (the “terminator”), which are the highest-resolution color images ever obtained of Mercury’s surface. • At the beginning of this movie, it is dawn in that region of Mercury, and the Sun is just off the horizon. The long shadows that are cast by crater walls exaggerate the ruggedness of the terrain and highlight variations in topography. • Though Mercury’s true colors are subtle, the 11 color bands of MDIS were combined in a statistical method used to highlight differences in color units. Older, low-reflectance, and relatively blue material is encroached by younger, relatively red smooth plains. Several lobate scarps or cliffs are observed, which are places where compressional stresses caused Mercury’s crust to fracture and shorten. http://messenger.jhuapl.edu/news_room/presscon5_images/Robinson%20Image%205.7.mov

29. Mercury Much of the image to the right of the Kuiper crater (in the centre here) had never been imaged by a spacecraft before. Researchers were surprised to see long crater rays that extend thousands of kilometers from a crater at the planet's north pole http://space.newscientist.com/data/images/ns/cms/dn14893/dn14893-1_450.jpg

30. Mercury Dark material, shown in deep blue in the enhanced colour image at right (a composite of visible and near-infrared images), was kicked up by impacts. The material seems to be widespread but patchy, suggesting the planet's interior is not homogenous. http://space.newscientist.com/data/images/ns/cms/dn15077/dn15077-1_600.jpg

31. Mercury • Double ringed basin • 290 km in diameter • Appears young (few craters on it) • ~ 1 billion years old • Lava may have covered up the central part of the basin http://messenger.jhuapl.edu/gallery/sciencePhotos/pics/presscon6_img4_5_lg.jpg

32. 160 km in diameter http://en.wikipedia.org/wiki/File:Mercury_Double-Ring_Impact_Basin.png

33. Spectra of Mercury Weak to absent absorption features – no iron in the silicates

34. Mercury’s Surface • Made of Enstatite (MgSiO3) – Mg-rich pyroxene • Made of material like the Lunar Highlands • Plagioclase feldspar - CaAl2Si2O8

37. Venus • orbit: 0.72 AU from Sun • diameter: 12,103.6 km (94.9% of Earth) (called Earth‘s twin) • mass: 4.869 x 1024 kg (81.5% of Earth) • Temperature on surface: 726 K(average) • Satellites: Zero

39. Venus’ atmosphere • Atmospheric pressure at surface is 92 times the pressure on the Earth’s surface • Atmospheric content: • Carbon dioxide 96.5 % • Nitrogen 3.5 % • Sulfur dioxide 150 ppm • Argon 70 ppm • Water vapor 20 ppm

40. Venus’ clouds • Venusian clouds are thick and are composed of sulfur dioxide and droplets of sulfuric acid. • These clouds reflect about 75%of the sunlight that falls on them,

41. Greenhouse Effect • The greenhouse effect is the rise in temperature that a planet experiences because certain gases in the atmosphere (H2O, CO2, CH4) trap energy emitted from the surface. • Visble light hits the surface • Surface warms and emits infrared radiation • Atmospheric gases absorb some of the infrared light • Surface and Atmosphere heat up

43. Stefan-Boltzman Law Emitted power (per square meter of surface) = σT4 λ·Tmax = 2,900,00 nm

46. Runaway Greenhouse Effect • Runaway greenhouse effect to describe the effect as it occurs on Venus • Venus is sufficiently strongly heated by the Sun that water is vaporized and so carbon dioxide is not reabsorbed by the planetary crust

49. Why does Venus has such a thick atmosphere? • The luminosity of the Sun has increased by 25% from 3.8 billion years ago • The atmosphere of Venus up to around 4 billion years ago maybe was more like that of Earth with liquid water on the surface. • The runaway greenhouse effect may have been caused by the evaporation of the surface water and the rise of the levels of greenhouse gases that followed.

50. Surface • Mapped by Magellan spacecraft (1990-1994) • How was it mapped if it has a dense atmosphere?