1. EART160 Planetary Sciences Mikhail Kreslavsky

2. The Solar System consists of: Stars: –The Sun Planetary bodies  regular shape (~sphere)  layered internal structure  own thermal history Small bodies  irregular shape  too small for own thermal history OR  fragments of planetary bodies Interplanetary medium –Dust –Particles –Fields

3. Materials of the Solar System EART160 Planetary Sciences

4. Methods of study of materials (a very general classification) Remote sensing mostly with electromagnetic waves mostly spectroscopy –For atmospheres: Extremely high sensitivity (qualitative detection of species) Moderately accurate (quantitative measurements) –For solid surfaces Moderately sensitive and rather ambiguous (though widely used) Laboratory studies of samples …Miraculous… …fantastic… …astonishing… Contact methods out of laboratory (e.g., robotic labs on other planets) Very limited so far, but improving…

5. Solar System materials accessible in laboratory Terrestrial materials –abundant –mostly from the upper crust, but also some lower crust and mantle –almost no old materials Lunar samples –3 Luna missions, 6 Apollo missions; incl. old material; ~385 kg Asteroid samples –A few ~10 micron particles from Itokawa (Hayabusa mission) Comet samples –Dozens of ~10 micron particles (Stardust mission) Interplanetary / interstellar dust decelerated in the upper atmosphere of the Earth and gathered in stratosphere –contains (~10%) the only lab-accessible non-Solar-System material Meteorites: –Samples of original very old non-planetary material (“chondrites”) –Samples of shallow (“achondrites”) and deep (“irons”) interior materials of destroyed planetary bodies –Samples of lunar upper crust –Samples of martian upper crust

6. Solar System materials accessible in laboratory Terrestrial materials –abundant –mostly from the upper crust, but also some lower crust and mantle –almost no old materials Lunar samples –3 Luna missions, 6 Apollo missions; incl. old material; ~385 kg Asteroid samples –A few ~10 micron particles from Itokawa (Hayabusa mission) Interplanetary / interstellar dust decelerated in the upper atmosphere of the Earth and gathered in stratosphere –contains (~10%) the only lab-accessible non-Solar-System material Meteorites: –Samples of original very old non-planetary material (“chondrites”) –Samples of shallow (“achondrites”) and deep (“irons”) interior materials of destroyed planetary bodies –Samples of martian upper crust –Samples of lunar upper crust 1μm1μm

7. “Iron” “Rock”

8. Meteorites: Chondrites: –Condensed from gas phase –Contain chondrules –Have never been into planetary bodies –Aqueous alteration of some of them Achondrites: –Solidified from melts –Often were disintegrated and re-aggregated –material of planetary bodies –“rocks” and “irons”

10. Ca-Al-rich inclusion (CAI) Such inclusions in chondrites are 4.6 Ga old; the oldest material in the Solar System Chondrites

12. The main message: In some sense, all Solar System objects have the same composition… –More accurately, ratios of abundances of rare earth elements, stable non-radiogenic isotopes of refractory elements are the same with high accuracy  All Solar System bodies have been formed from (almost) the same well-mixed material Extra-solar material (dust particles) have different composition (ratios of REE, isotopes, etc.)

13. Chondrites have the same composition as the Sun (except volatiles). This is THE composition of the Solar System. All compositional variations of planetary materials are due to differentiation of this primordial material

14. What word “metal” means for… Astrophysicists: –All elements except H or He (and sometimes Li, Be, B) Chemists / geochemists: –80% of elements except H and the upper right corner of the periodic table Physicists: –Specific type of condensed matter, mostly (but not only and not always) crystalline phases of those 80% of elements Geophysicists, planetologists (in some context) –Material of some meteorites and of cores of the Earth and planetary bodies

15. What word “rocks” means for… Normal people: –Stones, boulders, etc. Geologists / geochemists: –(types) of naturally occurring aggregates of solid-state phases (e.g., basalts, granites, etc.) Geophysicists, planetologists (in some context) –Silicate material of planetary bodies “metals” “rocks” “ices” – major types of solid planetary materials Geochemists, planetologists (in other context) –Type of meteorites (other than “irons”)

16. Meteor – a phenomenon in upper atmosphere (“shooting star”) Meteoroid – small body in space (~ 1 cm – 100 m) Meteorite – meteoroid softly decelerated in the atmosphere and safely landed on a planet Meteoritics studies meteorites Meteorology studies weather

17. Planetary Surfaces EART160 Planetary Sciences

18. How many planets in the Solar System have surfaces?

19. Resurfacing: Endogenic –Volcanism –Tectonics Exogenic –Meteoritic impacts and space weathering –Mass wasting –Action of atmosphere and hydrosphere

20. Planetary Surfaces – impact processes EART160 Planetary Sciences

21. Hypervelocity impacts: Impact velocity >> speed of sound in the target and in the projectile –Minimal impact velocity ~ escape velocity –How to estimate a typical / maximal impact velocity? First approach: quick release of much energy in little volume (explosion) –Crater size depends on impact energy only mv 2, not m nor v nor impact angle –Crater morphology depends on crater size only –This first approach is valid approximately –This first approach fails for very oblique impacts

22. Crater Sizes A good rule of thumb is that an impactor will create a crater roughly 10 times the size (depends on velocity) We can come up with a rough argument based on energy for how big the transient crater should be: 2r v 2R E.g. on Earth an impactor of 0.1 (1) km radius and velocity of 10 km/s will make a crater of radius 2 (12) km For really small craters, the strength of the material which is being impacted becomes important Does this make sense? 

23. Very oblique impacts

24. Strength regime –Smaller craters –Weaker gravity –Stronger material  Compression  Excavation Simple craters Gravity regime –Larger craters –Stronger gravity –Weaker material  Compression  Excavation  Modification Simple craters (smaller) Complex craters (larger) Basins (largest) Phases of impact process: Post-impact modification

25. Microcrater 10 micron diameter

26.  Compression  Excavation  Formation of transient cavity  Modification

27. Gravity regime:  Modification Simple craters (smaller) Complex craters (larger) Basins (largest)

29. Morphology of complex craters Ejecta Rim Walls Terraces Floor Central peak / peak ring The Moon, Crater Euler, D = 28 km

30. Morphology transition

31. Mimas 130 km diameter complex crater

32. 5 km Craters on Mars

33. 20 km Meteoroid – a rock in space Craters on Mars (thermal IR image)

34. 20 km Craters on Mars (thermal IR image)

35. 100 km Impact basin on Mars

36. 200 km Old impact basin, old and young craters on Mars (thermal IR image)

37. Complex craters on Venus (radar image)

38. Eroded simple and complex craters on Ganymede

40. Small impacts on atmosphereless bodies: Formation of planetary regolith Geochemical effects Mixing Specific surface structure

41. Impact craters… Tools for study of relative and absolute ages Probes for shallow subsurface Probes for past atmosphere … A useful thing …