Lecture #14 Tues Mar 16 General Relativity
History of gravity and motion of the planets
Aristotle/Ptolemy: circles
Kepler: ellipses
Newton: general theory of celestial orbits
Aristotle: planets must move in circles
Problem with retrograde motion of planets; Ptolemy (85-165) added ÒepicyclesÓ
Copernicus (1473-1543): heliocentric model more ÒnaturalÓ at
explaining retrograde motion.
Johannes Kepler (1571-1630) Ellipses much more accurate
than circles with epicycles.
Newton: objects move in straight lines (ÒinertiaÓ) unless acted upon by external force.
Newton proved mathematically that if the gravitational forced decreases with the square of the distance (Òinverse-square lawÓ) then planetary orbits would be ellipsesÉ
1781: William Herschel discovers a new planet, Uranus.
By 1820s orbit of Uranus deviated from predictions. 1845 Urbain Le Verrier and John Couch Adams predict a new planetÉ Neptune (ÒdiscoveredÓ 1846).
1859: Le Verrier announces discrepancies in orbit of Mercury (Òperihelion shiftÓ)É
1905: Einstein develops his theory of special relativity, only for constant, linear motion:
no change of speed or direction (no acceleration), no
gravity.
Special relativity: you cannot do an experiment to determine absolute motion.
General relativity: you cannot do an experiment to distinguish between gravity and acceleration (as in elevator thought-experiment). This is EinsteinÕs ÒEquivalence principleÓ (1907).
Equivalence principle + lots of math = general relativity (Einstein, 1916)
Basic idea: gravity caused by Òcurved spacetimeÓ
Curved spacetime
Observers who are accelerating will experience ÒcurvedÓ coordinate frames but are still traveling in a Òstraight lineÓ
You may have already experienced ÒgeodesicsÓ = Òshortest path on a curved surfaceÓ
EinsteinÕs general relativity: Gravity occurs because mass ÒbendsÓ spacetime.
Objects travel on ÒgeodesicsÓ = shortest distance on curved space time
Experimental consequences
¥ explains perihelion shift of Mercury
¥ predicts bending of light rays by gravity
¥ gravitational redshift
¥ gravity waves
General relativity predicts SunÕs gravity will bend path of starlight. Tested in 1919 during total eclipse.
Another prediction: light leaving a planetÕs gravity will be
Òredshifted.Ó Tested in 1969 by Pound and Rebka
One more prediction of general relativity: gravity waves. Indirectly detected in binary pulsars (Nobel Prize, Hulse and Taylor, 1993)
Summary of general relativity
General relativity goes beyond special relativity to include acceleration and gravity
General relativity: you cannot do an experiment to
distinguish between gravity and acceleration.
General relativity includes NewtonÕs theory of gravity for small masses and velocities
General relativity also explains the perihelion shift of Mercury.
General relativity predicts
¥ bending of light rays by gravity
¥ gravitational redshift
¥ gravity waves
¥ black holes (not unique to GR)
Evidence for supermassive black hole at center of our galaxy:
http://www.youtube.com/watch?v=EvuV3GdVaY4