Deck 10: The Deaths of Stars

A) 3.0*10¹⁰ years
B) 3.3*10⁹ years
C) 6.4*10⁸ years
D) 1.6*10¹¹ years
E) The age of a star cluster cannot be determined from the mass of stars at the turnoff point.

A) have life expectancies that are equal to the age of the cluster.
B) are stars that are just becoming white dwarfs.
C) are stars that are just entering the main sequence portion of their evolution.
D) are stars that are about to supernova.
E) are stars that are generally spectral type G stars.

A) Herbig-Haro object
B) globular cluster
C) open cluster
D) giant cluster
E) supernova

A) all stars formed in star clusters.
B) the sun was once a member of a globular cluster.
C) they give us a method to test the our theories and models of stellar evolution.
D) they are the only objects that contain Cepheid variables.
E) all of the above.

A) because helium is very explosive and cannot be controlled when the nuclear reactions occur.
B) because degenerate electrons in the core do not allow the core to expand as it heats up.
C) in Cepheid variables.
D) in stars with masses less than 0.4 M.
E) none of the above.

A) a planetary nebula.
B) a Bok globule.
C) an open cluster.
D) an absorption nebula.
E) a supernova remnant.

A) hydrogen
B) hydrogen and helium
C) hydrogen, helium and carbon
D) hydrogen, helium, carbon, and neon
E) hydrogen, helium, carbon, neon, and oxygen

A) hotter; larger
B) cooler; larger
C) hotter; smaller
D) cooler; smaller

A) turnoff-point
B) main-sequence
C) turnon-point
D) hydrogen-flash
E) horizontal-branch

A) it is less massive than about 3 solar masses.
B) it has become a red giant star.
C) it has formed a helium core.
D) the material in the core has gradually become degenerate.
E) All of the above must be true.

A) 1
B) 2
C) 3
D) 4
E) 5

A) turnoff points
B) horizontal branch
C) Lagrangian points
D) synchrotron points
E) radiation belts

A) 200 million years
B) 2 billion years
C) 10 billion years
D) 30 billion years
E) The age of the cluster cannot be estimated from an H-R diagram of the cluster.

A) accretion disk.
B) Lagrangian point.
C) Algol paradox.
D) planetary nebula.
E) supernova remnant.

A) a protostar.
B) a red giant star.
C) a white dwarf star.

A) Lagrangian radiation
B) Accretion
C) Ultraviolet radiation
D) Synchrotron radiation
E) Infrared radiation

A) all have the same age.
B) all have the same chemical composition.
C) all have the same luminosity.
D) all of the above.
E) a and b above.

A) Herbig-Haro object
B) globular cluster
C) open cluster
D) giant cluster
E) supernova

A) controls the pulsations in Cepheid variable stars.
B) is the nuclear fusion of hydrogen to helium in massive stars.
C) is the process that produces the neutrinos we receive from the sun.
D) requires a temperature of about 5,000,000 K to operate.
E) occurs during helium flash.

A) produce synchrotron radiation.
B) occur in regions of star formation.
C) not occur in old star clusters.
D) all be visual binaries.
E) repeat after some interval.

A) they do not contain helium.
B) they rotate too slowly.
C) they cannot heat their centers hot enough.
D) they contain strong magnetic fields.
E) they never use up their hydrogen.

A) 5 billion years
B) 57 billion years
C) 570 million years
D) 5 million years
E) 500 thousand years

A) Protostar, pre-main-sequence
B) Protostar, white dwarf
C) Protostar, main-sequence
D) Main-sequence, white dwarf

A) a very massive star.
B) a very young star.
C) a star undergoing helium flash.
D) a white dwarf in a close binary system.
E) a solar-like star that has exhausted its hydrogen and helium.

A) proton-proton chain
B) CNO cycle
C) triple alpha process
D) white dwarfs don't generate their own energy.

A) hydrogen nuclei and degenerate electrons.
B) helium nuclei and normal electrons.
C) carbon and oxygen nuclei and degenerate electrons.
D) degenerate iron nuclei.
E) a helium burning core and a hydrogen burning shell.

A) the expelled outer envelope of a medium-mass star.
B) produced by a supernova explosion.
C) produced by a nova explosion.
D) a nebula within which planets are forming.
E) a cloud of hot gas surrounding a planet.

A) 240 years
B) 790,000 years
C) 96,000 years
D) 960 years
E) 24,000 years

A) accretion disks can grow hot through friction.
B) neutron stars of more than 3 solar masses are not stable.
C) white dwarfs more massive than 1.4 solar masses are not stable.
D) stars cannot travel through space too fast.
E) stars with a mass less than 0.5 solar masses will not go through helium flash.

A) pressure due to nuclear reactions in a shell just below the surface keeps it from collapsing.
B) pressure does not depend on temperature for a white dwarf because the electrons are degenerate.
C) pressure does not depend on temperature because the white dwarf is too hot.
D) pressure does not depend on temperature because the star has exhausted all its nuclear fuels.
E) material accreting onto it from a companion maintains a constant radius.

A) the core of a massive star collapses.
B) hydrogen detonation occurs.
C) a white dwarf exceeds the Chandrasekhar limit.
D) the cores of massive stars collapse.
E) neutrinos in a massive star become degenerate and form a shock wave that explodes the star.

A) the degenerate nature of the hydrogen on the surface of the white dwarf.
B) synchrotron radiation.
C) the rate of expansion of the shock wave inside the supernova.
D) the rotation rate of a neutron star.
E) mass transfer between the two stars in a binary system.

A) produces an absorption spectrum.
B) produces an emission spectrum.
C) is contracting to form planets.
D) is contracting to form a star.
E) is the result of carbon detonation in a 1-star.

A) less than 50
B) 50
C) 150
D) 250
E) more than 250

A) in planetary nebulae.
B) by red dwarfs.
C) in massive stars as their iron core collapses.
D) in supernova remnants.
E) by neutrinos.

A) Hydrogen to helium
B) Helium to carbon and oxygen
C) Carbon to magnesium
D) Fusion goes all the way up to iron.

A) undergo thermonuclear fusion of hydrogen and helium, but never get hot enough to ignite carbon.
B) undergo thermonuclear fusion of hydrogen, but never get hot enough to ignite helium.
C) produce type I supernovae after they exhaust their nuclear fuels.
D) produce type II supernovae after they exhaust their nuclear fuels.
E) undergo carbon detonation.

A) the size and structure of the Crab nebula.
B) laboratory measurements of the mass of the neutrino.
C) the brightening of supernovae a few days after they are first visible.
D) underground counts from solar neutrinos.
E) the detection of neutrinos from the supernova of 1987.

A) objects with temperature below 10,000 K.
B) high-velocity electrons moving through a magnetic field.
C) cold hydrogen atoms in space.
D) the collapsing cores of massive stars.
E) a helium flash.

A) protostar
B) pre-main sequence
C) main sequence
D) giant

A) 50 K
B) 100 K
C) 500 K
D) 5,000 K
E) 25,000 K

A) an accretion disk will form around the white dwarf.
B) the material will cool off because it begins to move at high velocities.
C) the material will fall directly straight onto the surface of the white dwarf.
D) the white dwarf will produce a protostar.
E) the white dwarf's iron core will collapse.

A) a redder turn-off point
B) a bluer turn-off point
C) fewer stars
D) fewer luminous stars
E) more low mass stars

A) younger and contain fewer stars
B) younger and contain more stars
C) older and contain fewer stars
D) older and contain more stars
E) more luminous and cooler

A) a globular cluster.
B) a planetary nebulae.
C) a white dwarf.
D) a young massive star.
E) a supernova remnant.

A) Higher-mass stars burn through their nuclear fuel faster.
B) Lower-mass stars don't get their energy from that same nuclear fusion source as higher-mass stars.
C) Higher-mass stars have less hydrogen fuel to burn.
D) Lower-mass stars spend a longer time evolving to the main sequence.
E) All of the above are false.

A) the helium nucleus is known as an alpha particle.
B) it occurs very rapidly.
C) it requires a temperature three times greater than that of hydrogen fusion.
D) it is the third source of the primary fusion processes.
E) each reaction produces three carbon nuclei.

A) protostars.
B) brown dwarfs.
C) white dwarfs.
D) red giants.

A) hydrogen
B) hydrogen and helium
C) hydrogen, helium, and carbon
D) hydrogen, helium, carbon, and neon
E) hydrogen, helium, carbon, neon, and oxygen

A) is a main-sequence star.
B) is a pre-main-sequence protostar.
C) is a neutron star.
D) will become a white dwarf.

A) a planetary nebula.
B) a shell of hot, expanding gas with a white dwarf at the center.
C) a shell of hot, expanding gas with a pulsar at the center.
D) Nothing is ever left behind.

A) become hotter and more luminous.
B) become cooler and more luminous.
C) become hotter and less luminous.
D) become cooler and less luminous.
E) become larger in radius and hotter.

A) exceeding the Chandrasekhar limit.
B) losing mass.
C) gaining mass.
D) remaining at 8.5 solar masses.

A) brown dwarfs
B) white dwarfs
C) supergiants
D) supernovae

A) stars in each cluster all formed at about the same time all with the same mass.
B) the sun was once a member of a globular cluster.
C) stars in each cluster all formed at about the same time but with differing masses.
D) stars in each cluster all formed at different times with differing masses.
E) all of the above.

A) on the surface of the star.
B) in the center of the star's helium core.
C) on the outside of the star's helium core.
D) Neither helium nor hydrogen is being fused in the red giant stage.

A) replaced by fusion of hydrogen atoms into helium.
B) replaced by fusion of helium atoms into carbon.
C) not replaced.

A) supernova remnants.
B) planetary nebulae.
C) the result of uranium detonation.
D) the result of the collapse of the iron core of each star.
E) nebulae associated with protostars.

A) speed through space.
B) oxygen content.
C) uranium content.
D) anti-matter content.
E) mass.

A) show no effect.
B) explode recurrently as a nova.
C) blow up as a type I supernova.
D) answers B or C

A) a planetary nebula.
B) a name for the cloud of gas and dust which later became our solar system.
C) an ejected cloud of gas from a supernova.
D) in the constellation Orion, containing many bright young blue stars.

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

A) the most massive main-sequence stars.
B) lower-mass main-sequence stars.
C) A main sequence star stays a main-sequence star forever.
D) Main-sequence stars are formed from white dwarf stars.

A) nuclear energy it is generating.
B) its gravitational force.
C) Hubble's law of extragalactic redshifts.
D) degenerate electron gas pressure.
E) degenerate astronomers observing the star.