Deck 13: To the Graveyard of Stars: the End Points of Stellar Evolution

A) white dwarf
B) asymptotic giant branch
C) red giant branch
D) main sequence

A) thermal pressure
B) fusion
C) electron degeneracy pressure
D) the strong nuclear force

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

A) O and B stars
B) 25 and 10 solar mass stars
C) 10 and 5 solar mass stars
D) G and M stars

A) mass
B) color and composition
C) luminosity and temperature
D) color, distance, and brightness

A) The star's core expands, pushing out its envelope as well.
B) The star's envelope heats up.
C) The opacity in the outer layer increases.
D) The star's gravity decreases because of mass loss during fusion.

A) the Heisenberg uncertainty principle
B) the strong nuclear force
C) the Bohr model
D) the onion model

A) the star's composition
B) electromagnetism
C) the efficiency of fusion reactions
D) mass

A) main sequence
B) red giant
C) horizontal branch
D) asymptotic giant branch

A) a white dwarf from a 0.8 M_Sun star
B) a supernova from a 25 M_Sun star
C) a white dwarf from a 1 M_Sun star
D) a white dwarf from a 6 M_Sun star

A) fusion of hydrogen in the core only
B) fusion of hydrogen in the core and helium in a shell
C) fusion of helium in the core only
D) fusion of helium in the core and hydrogen in a shell

A) A
B) B
C) C
D) D

A) horizontal branch, main sequence, red giant, asymptotic giant branch
B) main sequence, asymptotic giant branch, red giant, horizontal branch
C) main sequence, horizontal branch, red giant, asymptotic giant branch
D) main sequence, red giant, horizontal branch, asymptotic giant branch

A) It is now 10,000 times larger.
B) It is now 600 times larger.
C) It is now 16 times larger.
D) It is now 16 times smaller.

A) environment.
B) composition.
C) mass.
D) distance.

A) Star A will transfer mass to star B.
B) Star B will transfer mass to star A.
C) The stars will merge.
D) Radiation from star B will disrupt star A.

A) main sequence and horizontal branch
B) main sequence and red giant
C) main sequence only
D) main sequence, red giant, horizontal branch, and asymptotic giant branch

A) It does not move.
B) downward and to the left
C) upward and to the left
D) upward and to the right

A) shocks from colliding winds around dying stars
B) planetary collisions
C) supernovae
D) fragmentation of giant molecular clouds

A) optical
B) radio
C) X-ray
D) gamma ray

A) The core becomes so hot it expands too much.
B) Iron cannot undergo fusion.
C) Iron does not produce energy when it undergoes fusion.
D) Iron requires such a high temperature for fusion that it does not occur inside stars.

A) It is 100 times larger at point 3.
B) It is 10 times larger at point 3.
C) It is 2 times larger at point 3.
D) It is 10 times smaller at point 3.

A) Type Ia supernovas
B) gamma-ray bursts
C) Type II supernovas
D) novas

A) the Big Bang.
B) supernova explosions.
C) winds from asymptotic giant branch stars.
D) cosmic ray collisions.

A) hydrogen burning
B) helium burning
C) oxygen burning
D) silicon burning

A) The core temperature increases.
B) The star produces less energy per fusion reaction.
C) The core density increases.
D) all of the above

A) the Big Bang
B) nova explosions
C) supernova explosions
D) winds from asymptotic giant branch stars

A) neutron star
B) white dwarf
C) black hole
D) Such a star does not leave a remnant.

A) magnetic fields
B) accretion disk
C) binary companion
D) all of the above

A) The star begins to fuse iron into nickel.
B) The star begins to pulsate as a variable star.
C) The star becomes a planetary nebula.
D) The star can no longer support itself against gravity.

A) neutrinos
B) radioactive nickel
C) gamma rays
D) optical light

A) 10 solar luminosities
B) 0.1 solar luminosities
C) 0.01 solar luminosities
D) 10-4 solar luminosities

A) The star becomes more luminous.
B) The efficiency of energy generation decreases due to helium fusion.
C) The star's interior heats up.
D) The star becomes larger.

A) Dust forming in the star's envelope is opaque to its radiation.
B) Mass is lost during each of the star's pulsations.
C) The loss of fusion energy in the star's core means that the outer layers are no longer gravitationally bound.
D) The outer layers become too hot to be gravitationally bound.

A) Earth
B) the United States
C) a small city
D) a football stadium

A) oxygen fusing into iron
B) oxygen fusing into silicon
C) carbon fusing into neon
D) the triple alpha reaction

A) A
B) B
C) C
D) The answer cannot be determined from this HR diagram.

A) adding metallic elements
B) smaller electron velocities
C) compressing the object
D) faster fusion reactions

A) gamma-ray burst.
B) Type II supernova.
C) Type Ia supernova.
D) none of the above.

A) gamma-ray burst.
B) nova.
C) active galactic nucleus.
D) Type II supernova.

A) the white dwarf's interior cooling to low temperatures
B) the white dwarf's companion evolving onto the horizontal branch
C) the white dwarf undergoing a thermonuclear runaway on its surface
D) the white dwarf becoming tidally locked to its companion

A) pulsar's magnetic axis is shifting with time.
B) pulsar is moving away from the observer.
C) pulsar has a binary companion.
D) pulsar's radiation carries angular momentum.

A) 10³ Mpc
B) 10⁸ Mpc
C) 10⁶ Mpc
D) 10⁵ Mpc

A) shock waves from rebounding gas.
B) absorption of light from the collapsing core.
C) neutrino flows.
D) magnetic fields.

A) the strong nuclear force becomes repulsive.
B) neutrinos push the material outward.
C) jets from a gamma-ray burst push it outward.
D) high-energy gamma rays push it outward.

A) main sequence star
B) nova
C) Type Ia supernova
D) Type II supernova

A) photoionization from a very massive star.
B) the death of a massive star.
C) the death of an intermediate mass star.
D) magnetized jets during star formation.

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

A) Their magnetic fields oscillate.
B) They have hot spots on their surfaces.
C) They are periodically blocked by binary companions.
D) Their radiation sweeps across Earth periodically.