Deck 11: Neutron Stars and Black Holes

A) A gravitational blue shift
B) The solar wind
C) A gravitational redshift
D) A X-ray burst
E) A pulsar wind

A) gravitational radiation.
B) time dilation.
C) gravitational curvature.
D) gravitational redshift.
E) hyperspace drag.

A) is believed to be a singularity.
B) is a crystalline layer.
C) has a radius equal to the Schwarzschild radius.
D) marks the inner boundary of a planetary nebula.
E) is located at the point where synchrotron radiation is created around a pulsar.

A) Roche limit
B) Lagrangian point
C) Chandraskhar limit
D) Hubble radius
E) event horizon

A) light does not escape from their event horizon.
B) most lie beyond dense dust clouds.
C) they have only a small surface area from which to emit.
D) the peak of their thermal emission is at much shorter wavelengths than visual.
E) they have only a small surface area from which to emit and the peak of their thermal emission is at much shorter wavelengths than visual.

A) about the same as that of a white dwarf.
B) about the same as that of the Sun.
C) about the same as an atomic nucleus.
D) zero.

A) white dwarf; neutron star
B) neutron star; black hole
C) pulsar; neutron star
D) pulsar; white dwarf
E) white dwarf; black hole

A) the central star of the Crab nebula
B) the Orion nebula.
C) LMC X-3
D) Algol
E) PSR 1257+12

A) Hypernovae
B) Collapsars
C) Pulsars
D) Kerr singularities
E) Magnetars

A) supernovae that occur when two red dwarfs collide.
B) supernovae that occur when 10-solar-mass stars explode.
C) supernovae that occur when stars more massive than 25 solar masses explode.
D) one theory to explain the production of gamma-ray bursters.
E) supernovae that occur when stars more massive than 25 solar masses explode and one theory to explain the production of gamma-ray bursters.

A) less than 3 solar masses.
B) more than 3 solar masses.
C) between 0.4 and 1.4 solar masses.
D) less than 0.4 solar masses.
E) not larger than the masses of the stars that we can see.

A) the bursts were not produced among stars in the disk of our galaxy.
B) the bursts were not produced among stars in the nuclear bulge of our galaxy.
C) the bursts are not associated with planets in our solar system.
D) the bursts were not produced in our Sun.
E) All of the other choices are correct.

A) white dwarfs are not that common.
B) white dwarfs are not dense enough.
C) white dwarfs do not have magnetic fields.
D) a white dwarf spinning that fast would fly apart.
E) All of the other choices are correct.

A) they conserved angular momentum when they collapsed.
B) they have high orbital velocities.
C) they have high densities.
D) they have high temperatures.
E) the energy from the supernova explosion that formed them made them spin faster.

A) about the same as that of our Solar System.
B) about the same as that of the Sun.
C) about the same as Earth.
D) smaller than any of these.

A) I
B) III
C) II & III
D) I, II, & III
E) I, II, III, & IV

A) black hole
B) neutron star
C) white dwarf
D) supernova remnant
E) red dwarf

A) they are losing angular momentum into space via outward streaming particles.
B) they are dragging companion stars around in their magnetic field.
C) they are getting tired.
D) of conservation of angular momentum.
E) their mass is increasing.

A) several time that of the Sun.
B) about the same as that of the Sun.
C) about the same as Earth.
D) smaller than any of these.

A) A few kilometers away
B) A few solar radii away
C) A few astronomical units (AU) away
D) A few parsecs away

A) I & III
B) I & IV
C) II, III, & IV
D) I, III, & IV
E) I, II, III, & IV

A) Jocelyn Bell
B) Isaac Newton
C) Albert Einstein
D) Walter Baade
E) Edwin Hubble

A) 6 km.
B) 4 km.
C) 2 km.
D) 12 km.
E) 36 km.

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

A) black hole
B) neutron star
C) white dwarf
D) main-sequence stars

A) 10⁶ nm
B) 3 nm
C) 3 × 10⁶ nm
D) 1 nm
E) 3 × 10¹¹ nm

A) 3 km.
B) 1,500,000 km, the size of the Sun.
C) 150,000,000 km or 1 AU.
D) 3 × 10¹³ km or 1 pc.

A) the material will experience time dilation.
B) the material will become hotter.
C) the material will produce an absorption spectrum.
D) the material will appear to us to fall into the black hole very rapidly.
E) the material will experience time dilation and the material will become hotter.

A) pulsars are too hot to emit visible light.
B) pulsars contain black holes that won't let visible light escape.
C) the gravitational field of a pulsar is so great that the visible light emitted is redshifted.
D) pulsars are too far away for the visible light to be bright enough to be detected at Earth.
E) A few pulsars do emit visible light pulses.

A) smaller than the speed of light.
B) equal to the speed of light.
C) much larger than the speed of light.
D) irrelevant since nothing (including light) can escape from a black hole.

A) Science requires that experimental and theoretical findings be reproducible.
B) All scientists are bound by a code of ethics preventing them from publishing fraudulent work.
C) Scientific results are reviewed by other scientists before they are published.
D) Scientific journals only allow certain highly trusted individuals to publish their work.
E) Science requires that experimental and theoretical findings be reproducible and scientific results are reviewed by other scientists before they are published.

A) single stars that emit large amounts of X-rays.
B) X-ray binaries where the compact companion has a mass in excess of 3 .
C) large spherical regions from which no light is detected.
D) pulsars with periods less than one millisecond.
E) pulsars that are orbited by planets.

A) believed to be the result of mass transfer from a companion that increased the spin of the pulsar.
B) all single objects.
C) not spinning as rapidly as they seem because they have four hot spots that produce the flashes.
D) X-ray binaries.
E) gamma-ray bursters.

A) is found outside the event horizon.
B) is located within the event horizon.
C) can only be located if the black hole is in a binary system.
D) doesn't exist since all black holes have a finite size.

A) hydrogen.
B) helium and energy.
C) degenerate electrons.
D) neutrons and neutrinos.
E) large amounts of radio radiation.

A) there would be no light source nearby.
B) it would not be rotating rapidly.
C) it would be stationary.
D) very little matter would be falling into it.
E) there would be very few stars behind it whose light the black hole could block out.

A) I, II, III, & IV
B) I & II
C) I & III
D) I, II, & IV
E) I, III, & IV

A) the material will produce synchrotron radiation.
B) hydrogen nuclei begin to fuse and emit high-energy photons.
C) the material will become hot enough that it will radiate most strongly at X-ray wavelengths.
D) as the material slows down it converts thermal energy to gravitational potential energy.
E) None of the other choices are correct.

A) a very massive object of finite size.
B) a shell of material expanding from a white dwarf.
C) a massive body of infinitely small size.
D) a burnt out white dwarf.

A) n, white dwarfs
B) ν, neutron stars
C) n + ν , white dwarfs
D) n + ν , neutron stars

A) ˜6.75 hours
B) ˜5 hours
C) ˜12 hours
D) ˜3.5 hours

A) lighthouse, neutron star
B) scientific, white dwarf
C) Earth-centered, neutron star
D) mathematical, Earth

A) planets
B) neutron stars
C) black holes
D) neutron stars or black holes

A) solid
B) fluid
C) gas
D) All of the other choices are correct.

A) Electron degeneracy pressure can no longer support the core and the electrons combine with the protons to generate neutrons and neutrinos, the neutrinos of which supply neutron degeneracy pressure to support the neutron star.
B) Electron degeneracy pressure can no longer support the core and the electrons combine with the protons to generate neutrons and neutrinos, the neutrons of which supply neutron degeneracy pressure to support the neutron star.
C) Electron degeneracy pressure supports the core of the white dwarf.
D) Electron degeneracy pressure can no longer support the core and the electrons combine with the protons to generate neutrons and neutrinos, the neutrinos of which supply neutron degeneracy pressure to support the black hole star.

A) moving away from Earth
B) moving towards Earth
C) in motion perpendicular to the line-of-sight
D) in motion perpendicular to the line-of-sight followed by motion towards Earth

A) circle
B) line
C) sphere
D) square

A) light with wavelengths in the black color region.
B) no light from inside the event horizon.
C) light which is blueshifted to shorter wavelengths as it escapes.
D) light which is redshifted to shorter wavelengths as it escapes.

A) 0
B) 1
C) 2
D) 3

A) black hole, neutron star, white dwarf
B) white dwarf, neutron star, black hole
C) black hole, white dwarf, neutron star
D) neutron star, white dwarf, black hole

A) black holes
B) neutron stars
C) white dwarfs
D) All of the other choices are correct.

A) 10 times per second
B) 1 time per second
C) 100 times per second
D) 1000 times per second

A) white dwarf
B) neutron star
C) black hole
D) None of the other choices are correct.

A) pulsar
B) neutron star
C) white dwarf
D) black hole

A) The core collapses into a black hole.
B) The core collapses into a neutron star.
C) The core collapses into a white dwarf.
D) The core collapses into a neutron star or a black hole.

A) white dwarf, electron degeneracy pressure
B) neutron star, neutron degeneracy pressure
C) black hole, no pressure (i.e., it will not be supported)
D) white dwarf, neutron star, or black hole; electron degeneracy, neutron degeneracy, and no pressure, respectively.

A) The core collapses to a black hole.
B) The core collapses to a neutron star.
C) The core collapses to a white dwarf.
D) The core collapses to a neutron star or a black hole.

A) visual
B) gamma
C) X-ray
D) All of the other choices are correct.

A) electron, neutron, black hole
B) black hole, neutron, electron
C) neutron, electron
D) electron, neutron