Deck 20: White Dwarfs, neutron Stars, and Black Holes

A)It becomes hotter and brighter
B)It becomes hotter and dimmer
C)It becomes cooler and dimmer
D)It becomes cooler and brighter

A)Greatest mass a white dwarf can have
B)Most massive main sequence star that can exist
C)Distance at which parallaxes can no longer be measured
D)Maximum brightness of a supernova

A)The nearest white dwarf is thousands of parsecs away
B)White dwarfs are very small in size
C)Even the hottest white dwarf is very cool
D)White dwarf stars are surrounded by thick dust shells

A)Spinning neutron stars with beamed radio emission
B)Black holes with accretion disks
C)Pulsating red giant stars with close companions
D)White dwarfs with periodic stellar winds
E)Binary systems with regular eclipses

A)1 solar mass
B)1.4 solar masses
C)2.5 solar masses
D)5.2 solar masses

A)Nearly 100%
B)About 1 in a 100
C)About 1 in 10
D)None have masses that large

A)1/100 as large
B)The same
C)100 times as large
D)10,000 times as large

A)White dwarf
B)Main sequence star
C)Red giant
D)Neutron star

A)It is about to become a white dwarf
B)It is about to produce a supernova outburst
C)It is a main sequence star
D)It is a proto-star

A)Many of them rotate faster than once per second
B)They are about as large as the Moon
C)They have small magnetic fields
D)They eventually become supernovas.

A)A white dwarf
B)A neutron star
C)A main sequence star
D)A pulsar

A)Radius is independent of mass
B)More massive white dwarfs are larger
C)More massive white dwarfs are smaller
D)All white dwarfs have the same size

A)It is larger and lower in density
B)It is larger and higher in density
C)It is smaller and higher in density
D)It is smaller and lower in density

A)Radiation pressure
B)Degenerate electron gas pressure
C)Degenerate neutron gas pressure
D)Gas pressure from heat derived from fusion
E)Energy from recurrent novae

A)They have small radii and large densities
B)They have large radii and small densities
C)They have high luminosities and large radii
D)They have small masses and high luminosities

A)10 km
B)The size of the Earth
C)The size of the Sun
D)Between 1.4 and 2.5 solar radii

A)0.1km
B)10 km
C)1000 km
D)100,000 km

A)A massive O star
B)A neutron star
C)A 10 solar mass black hole.
D)An X-ray binary
E)A white dwarf

A)Degenerate neutron pressure
B)Radiation pressure
C)Normal gas pressure
D)Degenerate electron pressure

A)Nothing
B)Photons
C)Neutrinos
D)Antiparticles

A)It goes to zero
B)It becomes infinite
C)It becomes negative
D)It becomes equal to the speed of light

A)Move faster than the speed of light
B)Are redshifted
C)Turn into neutrinos
D)Produce a white hole

A)1 day older
B)More than 1 day older
C)Less than 1 day older
D)1 day younger

A)Radioactive decay
B)Release of gravitational potential energy
C)Rotational kinetic energy of the Crab Nebula pulsar
D)Nuclear reactions in the center of the nebula

A)Conserved angular momentum when it shrank
B)Has been struck a glancing blow by another star
C)Has formed from a very rapidly rotating gas cloud
D)Has been accelerated by explosions on its surface

A)Mass
B)Chemical composition
C)Age
D)Rate of accretion of new material

A)The star moves away from us at an increasing speed
B)The star grows steadily cooler
C)The star's gravitational redshift increases
D)The star becomes obscured by more and more interstellar dust

A)While studying radio scintillations in the solar wind
B)While studying rapidly variable stars
C)In globular clusters
D)In a search for 21 cm radiation from other galaxies.

A)Matter causes curvature of space
B)The gravity of a moving object varies with time
C)Gravitational forces exist only over a limited distance
D)Anti-matter has negative gravity

A)Black hole
B)Neutron star
C)Accretion disk
D)White dwarf

A)Matter causes space to exert gravitational forces
B)Matter curves space
C)Matter causes space to expand
D)Matter causes space to contract

A)Pulsar
B)White dwarf
C)Black hole
D)Quasar

A)Year
B)Day
C)Hour
D)Second

A)Synchrotron radiation
B)Black body emission
C)Bright line emission
D)Electron scattering

A)A white dwarf would break up if it rotated as fast as a pulsar
B)There is only one rate at which white dwarfs can rotate
C)White dwarf stars can't rotate
D)There are not enough white dwarfs to account for the number of known pulsars

A)Red light
B)Blue light
C)Violet light
D)No light (can't escape)
E)White light

A)Mass
B)Electric charge
C)Chemical composition
D)Angular momentum

A)A radio telescope
B)An optical telescope
C)An orbiting ultraviolet telescope
D)An infrared telescope

A)It cannot escape from the region around the star
B)It begins to travel faster than the speed of light
C)It has a strong blue shift
D)There is no longer any relationship between wavelength and energy

A)Gravitational collapse
B)Very rapid consumption of hydrogen
C)The collision between two stars
D)The impact of an antimatter asteroid on a star

A)A black hole.
B)A neutron star.
C)A red giant.
D)A white dwarf.

A)The first appearance of Comet Halley
B)The Crab supernova
C)The formation of a massive black hole in the galactic center
D)Alpha Centauri reaching the main sequence
E)A helium flash on Sirius

A)The same as the radius of the Earth
B)3 km
C)1 AU
D)21 cm

A)They occur in highly redshifted galaxies
B)They are all too faint to be nearby
C)They are confined to the plane of the Milky Way
D)They show no parallax

A)The Earth would spiral inward
B)The Earth would jump to a smaller orbit
C)The size of the Earth's orbit would increase rapidly
D)The Earth's orbit would remain the same

A)Mass and chemical composition
B)Age
C)Luminosity and temperature
D)Mass alone

A)A few hundredths of a solar mass
B)A few solar masses
C)A few tens of solar masses
D)A few thousand solar masses

A)7.5 km
B)15 km
C)60 km
D)120 km

A)Pulsar emission
B)Massive,mass-transfer X-ray binaries
C)Evolved red giants with masses in excess of 3 solar masses
D)Supernova explosions
E)Planetary nebulae

A)The depth to which we can see into the Sun
B)The surface of a black hole
C)The greatest distance to which we can see with current telescopes
D)The obscuration of starlight by interstellar dust

A)Black hole.
B)Neutron star.
C)White dwarf.
D)Red giant.