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The Life Cycles of Stars and our Sun Your Questions 1. Have you ever heard of the sun song by the group They Might be Giants? `Fun websites’: http://www.asu.edu/clas/hst/www/ahah/ Appreciating Hubble at Hyper-speed http://www.stsci.edu/outreach/ 1. How are distances between galaxies and between galaxy clusters calculated? The Hubble Flow v = Ho d (Ho = 71 km/s/Mpc) 1. Observer 1 sees both galaxies at distance d with speed v 2. Observer 2 sees the furthest galaxy at distance 2d, with speed 2v d v 1 d v 2 2. Elaborate on the difference between the Dark Matter theory and the MOdified Newtonian Dynamics theory (MOND). Describing Motion • Motion is when the position of an object changes in time • If position does not change, the object is at rest • The describe motions we need to monitor position and time • The rate at which an objects covers a given amount of space in a given amount of time is called speed v = d/t (when you add a direction to speed, it is called velocity) Acceleration • An acceleration is a change in velocity. • Acceleration occurs when either the magnitude or direction of the velocity (or both) are altered. • Uniform Circular Motion is Accelerated Motion Acceleration and Force • An object in constant velocity (or at rest) has no force acting on it. Or: if an object is being accelerated, there must be a net force acting on it (Newton’s first law) • Acceleration is caused by force but also related to the mass of the object (Newton’s second law) Force = Mass x Acceleration F = m·a Or a = F/m The gravitational force on an object near the surface of Earth is: Fgrav = m·g (g = 9.8m/s2) Gravity • We can summarize the universal law of gravitation with the following statements: – Every mass attracts every other mass through the force of gravity. – If mass #1 exerts force on mass #2, and mass#2 exerts force on mass#1, the force must depend o both masses, namely: – The force of attraction is directly proportional to the product of the two masses. – The force of attraction is inversely proportional to the square of the distance between the masses. The Law of Gravity Near Earth’s surface M 1M 2 Fg G 2 d G= 6.67x10-11 Fg gM 2 m3/kg/s2 M1 g G 2 d 2 9.8m/s d M1 M2 … so why don’t planets just fall into the sun? M1 M2 … because they miss it! v Fg M1 Fg M2 This is the concept of an orbit: M2 is being attracted by M1, which causes an acceleration, but has sufficient tangential velocity that the `fall’ becomes an orbit The same is true for galaxies: Their stars rotate around their center of mass. R If you know the distance of your star from the center, R, and its speed, v, you can calculate the mass of the galaxy contained within the radius R: M(<R) = v2 R / G For the sun: M(<8kpc) = 9x1010 Msun a = 2.5x10-8 cm/s2 And the acceleration: a= v2 / R …and when you reach the edges of galaxies… The `flat rotation curve’ seen beyond the visible edges of galaxies does not agree with the expectation that the galaxy `ends’. In this case one would expect a trend: v ~ R(-1/2) 1. DM: Fg = ma = GMm/r2 , a= GM/r2 Fc = m v2 / r (gravitational force) (centripetal force) Flat rotation curves imply `unseen’ mass in galaxies 2. MOND: F = m (a/ao) a = GMm/r2 ao = 1.2 10-8 cm s-2 Flat rotation curves stem from very small accelerations at the edges of galaxies, where the Newtonian dynamics is modified to imply: a= (Gmao)(1/2) / R and v ~ const. Current difficulties for MOND: 1. Gravitational lensing: (still in progress; recent MOND covariant formulation) 2. Density profiles of galaxy clusters