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Published byErnest Wilkins Modified over 9 years ago
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Stationary Elevator with gravity: Ball is accelerated down
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Outside of an accelerated elevator: Ball at rest
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Inside of accelerated elevator: ball accelerated down
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=elevator with gravity!
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General relativity Einstein’s fundamental insight: “ Equivalence principle” Gravity accelerates everything ⇒ Gravity must be a property of spacetime Gravity and acceleration are indistinguishable (Galileo) ⇒ Formulate physics in terms of accelerated frames
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Equivalence principle
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Elevator at rest
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Elevator in uniform motion
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Inside the moving elevator
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Accelerated elevator from outside
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Inside the accelerated elevator
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= In an elevator in a gravitational field
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Light bending: Gravity bends light Recall: light travels on spacetime geodesics ⇒ In spacetime with gravity, geodesics are curved Geodesics are the straightest possible lines ⇒ Gravity curves spacetime
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Spacetime curvature
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time spac e Spacetime curvature
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In curved space Parallel lines don’t stay parallel Triangles don’t add up to 180° The straightest possible lines are “geodesics” The stronger the curvature, the stronger theses effects
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In curved spacetime The actual length to a destination is changed (try this yourself!) The circumference of a circle is no longer 2πR (try this yourself!) Sometimes, more than one path is the shortest path (try this yourself!)
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What curves spacetime? Gravity curves spacetime We know that mass causes gravity ⇒ Mass curves spacetime
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What curves spacetime? Einstein’s most fundamental equation relates the curvature to mass: More mass, more curvature More curvature closer to mass Einstein’s equivalent to Newton’s law of gravity “Field equation”
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Is space curved?
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Light bending (2): Heavy objects curve spacetime Galaxy clusters are very heavy: 1000 trillion times more massive than the sun They should curve spacetime a lot Light should follow curved path around them
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Stretching of time
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Quantum mechanics: Particles are wave packets with wavelength and frequency Particle frequency is a “clock”: frequency = ticking rate Higher energy = higher frequency
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Stretching of time Quantum mechanics: Particles are wave packets with wavelength and frequency Particle frequency is a “clock”: frequency = ticking rate Higher energy = higher frequency Drop particle from top of tower It picks up speed, gains energy It picks up frequency Compare to particle at bottom: clock from top ticks faster
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Stretching of time Clock in gravitational field go slower Clocks in space go faster than on ground GPS satellites: extremely accurate clocks Easily measure gravitational time dilation
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Cut the elevator cable How to make light go straight g
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Then, light will go straight through the elevator
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Freely falling objects In a freely falling frame, light travels on straight lines Light travels on geodesics ⇒ Freely falling frames/objects travel on geodesics as well This is Einstein’s version of Newton’s first law Different starting velocity, different geodesic So, light must travel on very special geodesics
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Orbits as free-fall Planets orbit the sun, pulled by gravity only They are in free fall (no other force) Planet orbits are geodesics There are many different geodesics/orbits
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This astronaut is in free fall!
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Kepler motion Kepler motion applet
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Spacetime around a star A “star” is isotropic (the same in all directions) Mass Radius Spacetime around a star must be isotropic What is the curvature of spacetime around a star? What orbits do planets, particles, photons follow? What are the geodesics?
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Schwarzschild solution January 1916 in army hospital 2 months after Einstein invented GR Died 4 months later Solved the field equations Spacetime structure around spherical stars Describes how matter and light behave around stars (they follow geodesics) Far reaching implications... Karl Schwarzschild
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At large distances: It reduces to Netwon’s laws That’s where gravity is weak Schwarzschild solution C = 2πR R
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At large distances: It reduces to Netwon’s laws That’s where gravity is weak Close to star: Curvature stretches space: circumference of a circle C < 2πR Curvature stretches time: clocks go slower Add more mass: get more curvature Schwarzschild solution R
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Weak gravity...
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Stars... Stars are big: Solar radius 430000 miles Too big for any “extreme” properties to show ⇒ Slight effects only Orbits = geodesics “Almost” ellipses: Not closed (they “precess”) Light bending: stars behind sun slightly out of position
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Mercury orbit: Closest to sun: Strongest effect Observed to precess once every 23000 yrs Inconsistent with Newton’s laws Perfectly consistent with General Relativity Stars...
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Experiment during 1919 eclipse Eddington detected light deflection Initial accuracy relatively poor Confirmed later by radio imaging Sir Arthur Eddington Stars...
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Relativistic stars
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What happens when you make a star smaller and smaller? Effects become stronger and stronger... Light should go round and round... Clocks should go slower and slower...
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Relativistic stars What happens when you make a star smaller and smaller? Effects become stronger and stronger... Light should go round and round... Clocks should go slower and slower...
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Relativistic stars Make a star smaller than R s =2GM/c 2 curvature so strong it bends spacetime inside out Space and time switch roles inside R s : What is our time becomes space Forward in time on our clock means inward in radius for someone inside R s That means: Anything inside must continue to move inward Everything must go inward!
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Black holes Make a star smaller than R s =2GM/c 2 curvature so strong it bends spacetime inside out Inside R s everything moves inward No information can come back out ⇒ “Event horizon” Even light must stay inside Not light can escape ⇒ “black hole”
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Black holes Make a star smaller than R s =2GM/c 2 curvature so strong it bends spacetime inside out Inside R s everything moves inward No information can come back out ⇒ “Event horizon” Even light must stay inside Not light can escape ⇒ “black hole”
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Make a star smaller than R s =2GM/c 2 curvature so strong it bends spacetime inside out When does an object become a black hole? Sun: R s = 3km (2 miles) Earth: R s = 1cm (1/3 of an inch) Milkyway:R s = 1/2 lightyear Black holes earth white dwarf stars solar system neutron star galaxies galaxy clusters Black holes Radius Mass
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Black holes What happens near Horizon? To us: Clocks stop at R s ⇒ Light emitted at R s has zero frequency To us: Matter “freezes” at R s We never see it fall in To the infalling matter: Infalling clock ticks infinitely slowly ⇒ Infall takes a very short time Once inside, the only way is in
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Light paths Radius Time light cone
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Light paths Radius Time
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Kepler motion Explore Kepler orbits around Newtonian stars with the following applet: http://galileoandeinstein.physics.virginia.edu/more_stuff/flashlets/kepl er6.htm http://galileoandeinstein.physics.virginia.edu/more_stuff/flashlets/kepl er6.htm
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Tides: Moon pulls on one side of earth more strongly This causes the tides This means: Gravitational acceleration changes from place to place Curvature changes from place to place No universal freely falling frame
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Special relativity holds in a tiny, freely falling elevator But gravity is not uniform Different falling elevators accelerate at different rates ⇒ Spacetime is curved (every observer is different) Tides:
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Special relativity holds in a tiny, freely falling elevator But gravity is not uniform Different falling elevators accelerate at different rates ⇒ Spacetime is curved (every observer is different) Tides:
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Special relativity holds in a tiny, freely falling elevator But gravity is not uniform Different falling elevators accelerate at different rates ⇒ Spacetime is curved (every observer is different) That’s why we needed General Relativity in the first place! Tides:
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Tides near a black hole Black hole pulls on your feet stronger than on your head Your body will follow space- stretching Very slimming Very unhealthy
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