Deck 14: Neutron Stars and Black Holes

A) neutron gas pressure
B) hydrogen gas pressure
C) electron degeneracy pressure
D) neutron degeneracy pressure
E) hydrogen degeneracy pressure

A) be a neutron star or a black hole
B) be a neutron star, but not a black hole
C) be a black hole, but not a neutron star
D) not be a black hole or neutron star
E) not be a black hole or neutron star

A) type II supernovae
B) type Ia supernovae
C) type Ib supernovae
D) novae
E) planetary nebulae

A) 1
B) 1.4
C) 3
D) 8
E) 20

A) neutrinos and antineutrinos combine into neutrons
B) electrons and protons combine into neutrons and neutrinos
C) electrons and protons combine into neutrons and neutrinos
D) electrons and positrons combine into neutrons and neutrinos
E) protons and antiprotons combine into neutrons and neutrinos

A) collapsing stellar core exceeds the Schwarzschild limit
B) stellar core ignites iron fusion
C) collapsing stellar core exceeds the Chandrasekhar limit
D) stellar core exceeds the Roche limit
E) collapsing stellar core exceeds the Hawking limit

A) accreted helium suddenly fuses in a nova-like explosion
B) the Chandrasekhar limit is exceeded and the object collapses
C) carbon deflagration destroys the object
D) it merges with a binary companion
E) hydrogen fusion ignites in an accretion disk around it

A) is carried away as a 'pulsar wind' of high-speed atomic particles
B) produces strong gravitational waves that radiate for several light years
C) ionizes the supernova remnant around the pulsar
D) is in the form of neutrinos
E) is carried away by the high-energy beam emerging from the poles of the pulsar

A) time appears to slows down for them
B) time appears to speed up for external observers
C) they become squashed flat-their heads and feet are pushed together by gravitational tides
D) they become stretched thin-their heads and feet are pulled apart by gravitational tides
E) nothing appears to change

A) the pulsation of a neutron star's surface
B) a "hot spot" that rotates around the equator of a pulsar
C) a spinning beam of radiation emerging from the pulsar's poles
D) the rotation of an accretion disk transferring matter to the pulsar's surface
E) the revolution of a binary companion that eclipses the pulsar, then reveals it

A) fall into the black hole on a virtually straight path
B) spiral in to the black hole over several months
C) spiral in to the black hole over the course of several decades
D) continue in its normal orbit
E) spiral away from the black hole, pushed by gravitational waves

A) has a funnel shape, extending to the event horizon
B) glows in X-rays and gamma-rays from superheated surface
C) is invisible
D) would look like a dark sphere the size of Earth
E) emits blackbody radiation only

A) provide the energy to ionize supernova remnants
B) radiate gravitational waves
C) absorb matter from a binary companion through an accretion disk
D) emit short, regular bursts of radiation
E) undergo nova eruptions on a regular period of a few years

A) the radius of Earth
B) the radius of Mt. Everest
C) the radius of a grain of sand.
D) the radius of a helium atom
E) a radius of zero

A) is heated to millions of degrees through the loss of gravitational energy
B) is cooled to near absolute zero through the loss of gravitational energy
C) releases energy, all of which is absorbed by the black hole
D) never reaches the black hole due to the effect of time dilation
E) orbits the black hole but cannot cross the event horizon

A) emits regular pulses of radiation
B) has a defined event horizon that emits X-rays
C) has an accretion disk
D) has a mass greater than 1.4 solar masses
E) has a mass greater than 3 solar masses

A) speed up their rotation as they age
B) become more luminous as they age
C) emit lower energy radiation as they age
D) emit higher energy radiation as they age
E) slow down their rotation as they age

A) radiate orbital energy away as gravitational radiation and move farther apart
B) radiate orbital energy away as gravitational radiation and move closer together
C) exchange mass until their orbital periods become equal
D) exchange mass until they are in synchronous rotation
E) exchange angular momentum, lengthening the period of the pulsar

A) huge gas planets that could be classified as brown dwarfs
B) asteroids captured from interstellar space
C) observed, but not fully understood
D) predicted, but have not been observed
E) Earth-like, and may harbor life

A) the mass of the black hole is concentrated in a singularity
B) the accretion disk around the black hole contacts its surface
C) the escape velocity equals the speed of light
D) tidal forces ionize infalling gas
E) an infalling particle reaches equilibrium with radiation pressure

A) always contain pulsars, because pulsars supply the ionizing radiation
B) often last longer than a pulsar does, so the central pulsar may no longer be visible
C) rarely contain pulsars, because pulsar radiation disrupts the remnant
D) may not contain a pulsar, if the supernova explosion kicked the pulsar away at high speed
E) never contain pulsars

A) are created in supernova explosions of the most massive stars
B) result from the collision of two neutron stars
C) represent the youngest pulsars detected
D) result from long-term mass transfer from a companion star
E) are a theoretical prediction that has not been observed

A) is a compact object in a binary system
B) emits X-rays from a hot accretion disk
C) is accreting matter from a main-sequence companion
D) has a period of 5.6 days
E) has a mass of ten solar masses

A) an object so dense that light cannot escape its surface
B) a neutron star that has exceeded the Chandrasekhar limit
C) a theoretical model that has never been observed
D) an observed object that is not well understood
E) the result of a neutron star merger

A) radio and infrared
B) radio and X-ray
C) visible
D) visible and gamma-ray
E) X-ray and gamma-ray

A) rotate very rapidly
B) be very luminous
C) have weak magnetic fields
D) have a mass greater than three solar masses
E) have about the same surface temperature as the star that created them

A) accretion disk
B) binary star
C) gamma-ray burst
D) pulsar
E) magnetar

A) X-rays
B) atomic nuclei
C) neutrons
D) neutrinos
E) positrons

A) 10² g/cm³
B) 10 ⁵  g/cm ³
C) 10 ¹⁵  g/cm ³
D) 10^{2 5}  g/cm ³
E) 10 ⁵⁰  g/cm ³

A) magnetic fields
B) gravitational waves
C) angular momentum
D) mass transfer
E) pulsar winds

A) last minutes to hours
B) are detected primarily in the disk of the galaxy
C) occur without warning
D) are not associated with any observable event
E) are detected only a few times per year

A) the merger of two neutron stars
B) the collapse of a rapidly rotating massive star
C) the fusion of a layer of degenerate helium deposited on the surface of a neutron star
D) carbon deflagration in a neutron star
E) the crossing of jets from two compact objects

A) too weak to affect life on Earth
B) an important influence on mutation and evolution
C) the cause of the spectacular auroras at high latitudes
D) triggers for solar flares and coronal mass ejections
E) capable of causing mass extinction events

A) solar flares
B) the Aurora Borealis
C) nuclear reactor accidents
D) nuclear tests
E) particle accelerator leakage

A) hypernova
B) neutron star
C) black hole
D) jet
E) X-ray burster

A) spectral lines from fast-moving red- and blue-shifted ionized gas
B) gamma ray emission spectra
C) magnetic tubes in accretion disks
D) mass transfer from a binary star to a compact companion
E) pulsar rotation periods

A) charged particles
B) photons
C) gamma rays
D) helium atoms
E) hydrogen atoms