Deck 14: Neutron Stars and Black Holes: Strange States of Matter

A) red dwarf.
B) neutron star.
C) white dwarf.
D) black dwarf.
E) brown dwarf.

A) no longer rotating.
B) primarily iron and silicon.
C) made of compressed neutrons in contact with each other.
D) electrons and protons packed so tightly they are in contact.
E) constantly expanding and contracting.

A) extremely slow rotation and a strong magnetic field.
B) extremely rapid rotation and a strong magnetic field.
C) extremely rapid rotation and a weak magnetic field.
D) no rotation and a weak magnetic field.
E) no rotation and no magnetic field.

A) between 2 and 4 solar masses.
B) greater than 10 solar masses.
C) about 1.4 solar masses.
D) less than 1.0 solar masses.
E) 5.2 solar masses.

A) 0.08 to 0.4 solar masses.
B) 0.4 to 3 solar masses.
C) 1.4 to 3 solar masses.
D) 3 to 8 solar masses.
E) 6 to 11 solar masses.

A) a magnetar.
B) a white dwarf.
C) Supernova 1987A.
D) Cygnus X- 1.
E) a millisecond pulsar.

A) Carl Sagan
B) Jocelyn Bell
C) Anthony Hewish
D) Stephen Hawking
E) Martin Schwartzschild

A) coalescence of a neutron star binary.
B) hypernova- making black holes and bipolar jets.
C) collisions between two white dwarfs.
D) Both A and B are possible.
E) All three are possible.

A) In seconds, they radiate enormous amounts of energy.
B) They seem to be coming from far beyond our own Milky Way.
C) The beams may be bipolar ejections from the hypernova formation of black holes.
D) Millisecond flickering implies they are tiny in size.
E) They are scaled up X- ray bursters, with more massive objects involved.

A) the period of pulsation must speed up as the neutron star continues collapsing.
B) the star literally turns on and off like a lighthouse beacon.
C) the period of pulsation slows down due to the drag of the remnant on its field.
D) all pulsars must have their poles pointed directly toward us.
E) if the beam sweeps across us, we will detect a pulse of radiation.

A) X- ray
B) visible lighthouse
C) gamma- ray burster
D) ultraviolet repeating
E) radio

A) a white dwarf and a main- sequence star.
B) a white dwarf and a neutron star.
C) a contact binary system of two red giants.
D) two neutron stars in a mass transfer binary.
E) a main- sequence or giant star and a neutron star in a mass transfer binary.

A) a 6 solar mass black hole
B) a 1.8 solar mass neutron star
C) a 0.06 solar mass brown dwarf
D) a 1.5 solar mass white dwarf
E) a million solar mass black hole

A) periods of days or weeks.
B) weak or non- existent magnetic fields.
C) monopolar fields that switch polarity every rotation.
D) very strong bipolar magnetic fields.
E) no relation to pulsars.

A) millisecond- duration gamma- ray bursts.
B) a pulsar.
C) a neutron star.
D) a black hole.
E) Both B and C are correct.

A) It is a magnetar, with far more intense magnetic fields than any other.
B) Its period is much less regular than other pulsars.
C) It is the fastest spinning known pulsar.
D) It is relatively bright in shorter wavelengths, like visible and X- rays.
E) It is the oldest known pulsar.

A) rotating slowly.
B) most common in open clusters.
C) part of a binary system.
D) isolated in space.
E) collapsing rapidly.

A) generally form from 25- solar- mass stars.
B) spin very rapidly when they're young.
C) emit radio in all directions.
D) are the cause of gamma- ray bursts.
E) spin very slowly when they're young, and gradually spin faster as they age.

A) set of planets to orbit their neutron star host.
B) millisecond pulsar.
C) very visible supernova remnant.
D) black hole.
E) white dwarf and its planetary nebula.

A) It could eventually become a black hole, via a hypernova explosion.
B) It would blow off mass as an X- ray burster.
C) It would erupt as a Type I supernova.
D) It would grow larger, temporarily becoming a red giant again.
E) All of its protons and electrons would turn into quarks.

A) a remnant still visible to the naked eye.
B) a pulsar with a period of 33 milliseconds, visible optically.
C) the most famous black hole.
D) the closest known neutron star to our Sun.
E) no remaining visible trace, as it was a Type I supernova.

A) masses greater than 1.4 solar masses.
B) strong magnetic fields.
C) rotation periods comparable to the Sun's.
D) sizes comparable to large cities.
E) large surface gravities, compared to the Sun.

A) open clusters
B) globular clusters
C) extremely distant galaxies
D) emission nebulae
E) giant molecular clouds

A) not at least 25 solar masses.
B) between 1.4 and 2.0 solar masses.
C) Chandrasekhar's limit of 1.4 solar masses.
D) greater than Schwartzschild's limit of 3 solar masses.
E) less than 1.0 solar masses.

A) lighthouse
B) Bell
C) Einstein
D) Hawking
E) relativistic

A) They form from 1.4 solar mass stars.
B) They form an event horizon at twice the Schwartzschild radius.
C) Their escape velocity is greater than the speed of light.
D) Their event horizon is a physical surface boundary.
E) Their main- sequence mass was 5- 10 solar masses.

A) mergers of two black holes, and merger of a neutron star and a white dwarf
B) collisions between a white dwarf and a giant, and merger of two neutron stars
C) formation of uranium in the core of a supergiant, and collisions of white dwarfs
D) hypernova making pulsars, and mergers of two white dwarfs
E) hypernova making a black hole, and merger of two neutron stars

A) 4 km.
B) 15 km.
C) 36 km.
D) 100 km.
E) 3000 km.

A) Neutron
B) Proton
C) X- ray
D) Electron
E) Wolf- Rayet

A) look for its effects on a nearby companion.
B) search for their pulsar signal.
C) search for radio waves from the accretion disk.
D) look for voids in the star fields.
E) locate a visible star that disappears when the black hole passes in front of it.

A) we would immediately escape into deep space, driven out by its radiation.
B) our clocks would all stop.
C) all terrestrial planets would fall in immediately.
D) we would still orbit it in a period of one year.
E) life here would be unchanged.

A) an X- rays burster.
B) a millisencond pulsar.
C) a black hole.
D) a pulsar.
E) a gamma- ray burster.

A) visible light.
B) radio waves.
C) X- rays.
D) gamma rays.
E) nothing.

A) can be no bigger than the Earth, like white dwarfs.
B) can be no more than 1.4 solar masses, according to Chandrasekhar.
C) create the dark nebulae in the plane of the Milky Way.
D) lie in the cores of the most massive galaxies.
E) can be no bigger than a small city, just like neutron stars.

A) change color to a shorter wavelength.
B) slow down.
C) continue moving in a straight line.
D) bend towards the star due to gravity.
E) accelerate due to gravity.

A) 1604 BC.
B) 1054 BC.
C) 1054 AD.
D) 1592 AD.
E) 1604 AD.

A) X- rays if the matter was dense
B) visible light
C) gamma- ray bursts
D) radio waves if the matter was traveling fast enough
E) nothing

A) 0.25c.
B) 0.5c.
C) c.
D) 1.5c.
E) 2.5c.

A) the first gamma- ray burster to be spotted in other wavelengths as well
B) the strongest X- ray eclipsing binary system in the sky
C) a millisecond pulsar with three Earth- like planets around it
D) the brightest star in the constellation Cygnus
E) the leading candidate for an observable black hole binary system

A) Gravity is the result of curved spacetime.
B) Gravity is directly proportional to the mass of the attracting body.
C) Gravity is the opposite of the electromagnetic force.
D) Gravity can affect only massive particles, not massless photons.
E) Gravity is inversely proportional to the radius of the body.

A) to run backwards.
B) to run slowly.
C) to run faster.
D) to run the same as one on Earth.
E) to stop.

A) its length will decrease and its clock will run more slowly.
B) its length will decrease and its clock will run faster.
C) its length will increase and its clock will run more slowly.
D) its length will increase and its clock will run faster.
E) None of these will happen.

A) It is the third strongest source of X- rays in the sky.
B) The X- rays from the compact source vary in as little as a millisecond.
C) Spectroscopic data suggests hot gas is flowing toward the X- ray source.
D) The mass of the visible star is greater than that of the X- ray source.
E) The mass of the X- ray source is about 10 solar masses.