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Transcript
Summary from last lecture What is a planet? (solar system only for now!) (a) a body that is in orbit about the Sun (b) has sufficient mass for its self-gravity to overcome rigid body forces so that it assumes a shape under hydrostatic equilibrium (c) has effectively cleared the neighbourhood around its orbit. What is a planet? (solar system only for now!) (b) has sufficient mass for its self-gravity to overcome rigid body forces so that it assumes a shape under hydrostatic equilibrium => must be “round” (and not potato-shaped!) An irregular solid body will deform under self-gravity to hydrostatic equilibrium when: internal pressure ~ tensile strength c.f. Titan + Mercury or Pluto + Moon Solar system = 8 planets that satisfy a, b, and c + 5 dwarf planets: satisfies (a) and (b), but not (c) + not a satellite 8 planets + 5 dwarf planets 2003 EL61 “Haumea” 2009 Illinois “Easterbunny” “Makemake” What is a planet? (c) “Has effectively cleared the neigbourhood around its orbit” >1 Haumea 0.00067 Makemake 0.00067 Soter 2006; Astrophysical Journal 2.68x10-4 2.22x10-4 >100 0.02 0.02 Mercury from Mariner 10 First messenger flyby in January this year Happy Birthday NASA! mercury • 0.39 AU from the Sun: Kepler’s laws break down (General relativity) • e = 0.205 • Large Fe core, no atmosphere • Huge day -- night temperature variations • Some evidence of (water) ice near polar caps • Rotation period 58.6462 (Earth) days = 2/3 orbital period of 87.95 days. 3:2 resonance mercury • Rotation period 58.6462 (Earth) days = 2/3 orbital period of 87.95 days. 3:2 resonance • This 3:2 resonance “spin-orbit resonance” not due to chance! Simple relation between 2 timescales: day and year. • Mercury rotates only through 180 deg. between one perihelion and the next! • Tidal forces act to synchronise the orbit. Remember r-3 dependence => at perihelion, orbital and rotational motion are synchronised Venus: Earth’s sister(?) a = 0.73 AU e = 0.007 P = 225 (Earth)d M = 0.82 M_E R = 0.95 R_E Radar imaging Venus Venus Venus from Venera Venus’ retrograde orbit • Venus moves around the Sun in a retrograde orbit, with its surface moving about 60x slower than its upper atmosphere Venus’ retrograde orbit • retrograde orbit: puzzle. All other planets in prograde orbits! • Probably due to gravitational perturbations • Tilt b/w equatorial and orbital planes ~ 177deg! • As atmosphere developed, it could be significantly affected by tidal forces, perhaps leading to a damping effect
