Deck 18: Relativity and Black Holes

A)a reference frame that is not accelerating
B)a reference frame that is stationary with respect to the Earth
C)a reference frame that is in motion at constant speed
D)a reference frame that is accelerating at a constant rate
E)a reference frame in which there are strong gravitational forces

A)c/3
B)2c/3
C)c
D)4c/3
E)5c/3

A)how the speed of light varies with the motion of an observer
B)the length of the meter,but not the duration of the second
C)the rate each frame is accelerating
D)the results of physics experiments performed in each frame
E)whether events are simultaneous or not

A)a change in the wavelength of light caused by the motion of the light source
B)poor focusing of starlight caused by imperfections in the optics of a telescope
C)a change in the direction of starlight caused by its passage through the earth's atmosphere
D)an increase in the wavelength of light as it leaves the surface of a gravitating body
E)a change in the direction of starlight caused by the orbital motion of the Earth

A)The star's radius would increase.
B)The star could eventually become a black hole.
C)The star could erupt as a nova.
D)The star could exceed the Chandrasekhar limit and become a Type II supernova.
E)The star could eventually return to the top of the main sequence.

A)Relativity gives the same result as Newtonian physics when objects are moving slowly.
B)Relativity gives results that contradict many predictions of Newtonian physics,so we know the latter is incorrect.
C)Relativity must be better because it is a newer theory than Newtonian physics.
D)Newtonian physics and relativity make the same predictions,but it's easier to compute results using relativity.
E)Newtonian physics makes predictions that are at odds with certain observations,whereas relativity is consistent with those observations.

A)They are always moving at high speed,so they test relativity.
B)Relativity explains why we can see short-lived muons that are produced high in the atmosphere from cosmic rays.
C)We can see them being deflected from straight lines by the gravity of black holes.
D)They have a mass that does not increase if they are moving fast.
E)They are examples of Hawking radiation from black holes.

A)Energy
B)Radiation
C)Fusion
D)Gravity
E)Electric charge

A)Moving clocks run quicker.
B)The velocity of light depends on the speed of the observer.
C)Distances are shorter for objects traveling close to the speed of light.
D)Gravity arises because mass distorts spacetime.
E)Faster moving objects require less force to accelerate them.

A)It is a result of mass and energy being two forms of the same thing.
B)It is a consequence of distances getting shorter as objects move faster.
C)It is the result of the mass of falling bodies getting bigger because they are in motion.
D)It is the force that objects with mass exert on a body.
E)It is the result of the distortion in spacetime around an object with any energy density.

A)0.95c
B)0.995c
C)0.99995c
D)0.9999995c
E)0.999999995c

A)mass and gravity
B)light and energy
C)energy and mass
D)temperature and energy
E)distance and time

A)in terrestrial laboratories
B)inside our Solar System
C)when different observers are at rest with one another
D)when objects have a low mass
E)when objects are moving slowly

A)impossible,because nothing can travel that fast
B)possible,but not useful since they could not contain living beings
C)impossible,since objects that travel that fast would get shorter and squeeze out space for the astronauts to live
D)possible,if we are clever enough with new technologies
E)impossible,because they would require new energy sources that are not yet invented

A)It is a mental framework for keeping track of numbers in Newtonian physics.
B)Space and time form a two-dimensional region where physics takes place.
C)The term has no special meaning;it's just a fancy way to sound important when talking about physics.
D)It is the combined treatment of space and time in the theory of relativity.
E)It is the idea that observers will always measure the same locations and times of events.

A)the universe is homogeneous and isotropic
B)being stationary in a gravitational field is the same as being in an accelerated reference frame
C)at any radius inside a star the outward gas pressure must balance the weight of the material on top
D)mass and energy are interchangeable and neither can be destroyed
E)gravity does not exist in space

A)explains many things but can't explain everything
B)is accurate but contains some worrisome contradictions
C)is incorrect
D)only explains things in steady motion,but cannot be used to explain objects that accelerate
E)correctly accounts for the results of experiments in different reference frames

A)870 per second
B)1,150 per second
C)1,250 per second
D)1,366 per second
E)1,450 per second

A)1.00
B)1.67
C)1.80
D)1.90
E)2.05

A)No,because it would require us to set up physics experiments in faraway galaxies.
B)Yes,because even ordinary motion in automobiles and airplanes produces easily noticeable effects predicted by relativity.
C)No,because no one has been able to think of experiments that are able to measure the small differences between the predictions of Newtonian physics and relativity.
D)Yes,because (for example)subatomic particles can be accelerated to speeds approaching that of light.
E)No,because the theory of relativity contains paradoxes and contradictions,like the twin paradox.

A)There is no gravity out in space.
B)Gravity only happens when objects are accelerating.
C)In space,the gravity from the Moon and the Sun cancels out the Earth's gravity.
D)They and their spaceship are both freely falling at the same rate in the gravitational field.
E)The astronauts do not have any mass when they are out in space.

A)if two events take place at the same time,all observers will see that event simultaneously
B)whether events are seen as simultaneous or not depends on the motion of an observer
C)observers will always disagree on when an event took place
D)it is not possible to know when an event happened
E)moving observers can always know whether they are in motion

A)their paths through spacetime are curved in the presence of a massive body
B)their apparent speeds depend on the observer's frame of reference
C)they should not be attracted to a massive object
D)their wavelengths must remain the same as they travel through spacetime
E)their wavelengths would grow longer as they travel through empty space

A)0.05c
B)0.50c
C)0.95c
D)0.995c
E)0.99995c

A)1 kg
B)greater than 1 kg
C)less than 1 kg
D)different from 1kg,depending on what it's made of
E)larger than 1 kg because of the Sun's gravity

A)Spacetime is flat except inside the Schwarzschild radius of the Sun.
B)Relativity predicts Mercury has an orbital precession,but Newtonian physics does not.
C)Starlight passing near the Sun should be bent away from the Sun by its gravity.
D)Gravitational lensing should make Mercury brighter than it would otherwise be.
E)Mercury's orbital precession is a little bigger than predicted by Newtonian physics.

A)the photons are moving away from us very quickly as they are sucked into the black hole
B)the photons are moving increasingly faster in order to escape the pull of the black hole
C)the photons lose energy because climbing out of the black hole's gravity makes them tired
D)the curvature of spacetime is increasingly stretched near the black hole,which in turn stretches the wavelengths of the photons
E)time is moving increasingly slower as viewed from the observer's frame of reference

A)Their paths would be straight if they were moving slowly enough.
B)Their paths would curve more the closer they come to the massive object.
C)Their paths would curve by the same amount no matter how close they come to the mass.
D)Their paths would curve towards the mass if they passed close,but bend away from the mass if they passed far from the mass.
E)Their paths would curve less the closer they come to the massive object.

A)Her signals are shifted only slightly toward the red because she is orbiting well outside the event horizon of the black hole.
B)You would see her signals shifted to a much redder wavelength because she is close to the event horizon.
C)You would see nothing,because your colleague has crossed the event horizon around the black hole.
D)You would see nothing,because no light can escape the gravitational pull of a black hole no matter how far she is from it.
E)You would see her signals shifted to a much bluer wavelength because black holes can make highly energetic light.

A)It is the radius at which an orbiting object would show a precession.
B)It is the radius at which gravitational redshift can be detected.
C)It is the radius at which the black hole's spin equals the speed of light.
D)It is the radius at which the escape velocity equals the speed of light.
E)It is the radius at which a body falling onto the black hole would move at half the speed of light.

A)pulses of electromagnetic radiation
B)gravitational waves
C)high-energy particles
D)a slowing of clocks here on the Earth
E)redshifted light from the surface of the object

A)the point of maximum gravity
B)the radius of the original neutron star before it became a black hole
C)the radius from which shock waves course through spacetime due to the strong gravitational distortion of the black hole
D)the radius at which the escape speed from the black hole equals the speed of light
E)the radius at which the gravitational force is the same as that on the surface of the Sun

A)1/5
B)1/2
C)equal to
D)2 times
E)5 times

A)the mass when moving nearly the speed of light
B)the resistance to acceleration
C)the mass when near a black hole
D)the object's weight
E)the density divided by the volume

A)a black hole
B)the Sun
C)a white dwarf
D)a planet like the Earth
E)a neutron star

A)at approximately the same rate,but slightly slower.
B)significantly slower
C)significantly faster
D)sometimes faster,sometimes slower
E)at an equal rate,except during eclipses

A)extremely strong tidal forces
B)intense heating
C)strong Hawking radiation
D)strong infrared radiation
E)nothing

A)time dilation
B)the twin paradox
C)gravitational lensing
D)length contraction
E)mass increase

A)a star
B)dark matter
C)a black hole
D)any massive object
E)a white dwarf

A)You would see her signals unaltered in wavelength because she is orbiting well outside the event horizon of the black hole.
B)You would see her signals shifted to a much redder wavelength because she is close to the event horizon.
C)You would see nothing because your colleague has crossed the event horizon around the black hole.
D)You would see nothing because no light can escape the gravitational pull of a black hole no matter how far she is from it.
E)You would see her signals shifted to a much bluer wavelength because black holes can make highly energetic light.

A)The room is experiencing an acceleration from gravity.
B)The room is accelerating upward.
C)Both A and B at the same time.
D)Either A or B;it is impossible to tell the difference.
E)Either A or B,depending on whether massive objects in the room fall downward or float upward when released.

A)3 m
B)30 m
C)300 m
D)3 km
E)30 km

A)1 cm
B)1 m
C)1 km
D)10 km
E)200 km

A)the aberration of starlight
B)the gravitational field of the Earth
C)the solid crust of a terrestrial planet
D)the path followed by a freely-falling object in spacetime
E)the shape of a body that has mass

A)You would see his signals unaltered in wavelength because he is orbiting well outside the event horizon of the black hole.
B)You would see his signals shifted to a much redder wavelength because he is close to the event horizon.
C)You would see nothing,because your colleague has crossed the event horizon around the black hole.
D)You would see nothing,because no light can escape the gravitational pull of a black hole no matter how far he is from it.
E)You would see his signals shifted to a much bluer wavelength because black holes can make highly energetic light.

A)light emitted from matter falling onto a black hole
B)the gravitational redshift of light emitted near the event horizon
C)the radiation of particles created near the event horizon
D)high-energy X-rays and gamma rays from the formation of a black hole
E)the optical and infrared light from an energetic supernova explosion

A)black hole;the giant star is massive and could only be in orbit about something even more massive
B)black hole;its mass is too large to be a neutron star or a white dwarf
C)neutron star;any supernova that would have made a black hole would have destroyed the red giant
D)M-dwarf star;only such stars would be faint enough to go unseen in this system
E)black hole;most red giants orbit neutron stars,and neutron stars can turn into black holes

A)from sound waves produced by material falling onto the black hole
B)by tides produced on the Earth's oceans
C)through its Hawking radiation
D)through its gravitational effect on surrounding gas or stars
E)by looking for dark patches on the sky where the black hole swallows background light

A)by the watching the orbits of nearby stars
B)from the bending of the light from background stars
C)by finding objects that emit no light
D)by the X-rays produced by a surrounding accretion disk
E)by the detection of Hawking radiation

A)dark regions at the centers of galaxies
B)variable X-ray sources
C)extremely luminous infrared objects
D)objects that emit very faint radio emission
E)regular,repeated pulsations at radio wavelengths

A)the black hole rotates quickly
B)the black hole accretes material
C)a supernova explodes and forms a black hole out of its core
D)synchrotron radiation is emitted by infalling charged particles
E)a virtual pair of particles is created from the vacuum of space

A)are very old
B)contain many white dwarfs
C)have different physics than on the Earth
D)are rotating quickly
E)contain black holes

A)the signs of accretion onto black holes
B)the product of merging neutron stars
C)produced by the most energetic supernova explosions
D)the result of neutron stars accreting mass and turning into black holes
E)produced by intelligent life in the universe exploding nuclear bombs

A)much greater than it is now
B)the same as it is now
C)much smaller than it is now
D)larger or smaller,depending on the location of the Moon
E)irrelevant because Earth would be quickly fall into the Sun and be destroyed