Deck 10: Star Formation and Evolution

A) The light that passes though them is blue shifted due to the cloud's approach.
B) It dims the light of all more distant stars.
C) Even a little can completely block all light, such as the Horsehead Nebula.
D) Its motion causes the light of stars beyond to twinkle.
E) Its motion causes all light to be redshifted as it passes through these clouds.

A) only hydrogen.
B) 90% hydrogen, 9% helium by weight.
C) 10% hydrogen, 90% helium by numbers of atoms.
D) some hydrogen, but mainly carbon dioxide.
E) ammonia, methane, and water vapor.

A) it completely runs out of hydrogen.
B) it expels a planetary nebula to cool off and release radiation.
C) it explodes as a violent nova.
D) it builds up a core of inert helium.
E) it loses all its neutrinos, so fusion must cease.

A) 10,000 years.
B) 25,000 years.
C) 100,000 years.
D) a few million years.
E) 100 million years.

A) The core begins fusing iron.
B) The star uses up all its supply of hydrogen.
C) The carbon detonation explodes it as a type I supernova.
D) Helium builds up in the core, while the hydrogen burning shell expands.
E) The core loses all its neutrinos, so all fusion ceases.

A) 100 thousand years
B) Two million years
C) Fifty million years
D) One billion years
E) 4.6 billion years

A) the Crab Nebula.
B) the Andromeda Galaxy.
C) the Orion Nebula.
D) our Solar System.
E) the Helix Nebula.

A) When the T Tauri bipolar jets shoot out
B) In the middle of the main sequence stage
C) Red giant
D) Horizontal branch
E) Planetary nebula

A) Helium fusion gives more energy than hydrogen fusion does, based on masses.
B) Its outer envelope is stripped away and we see the brilliant core.
C) The core contracts, raising the temperature and increasing the size of the region of hydrogen shell-burning.
D) It explodes.
E) It immediately starts to fuse helium.

A) the star grows more luminous.
B) the star becomes less luminous.
C) helium is burning in the core.
D) the core is expanding.
E) hydrogen is burning in the central core.

A) Magnetism
B) Gravitation
C) The strong force
D) Radiation pressure
E) Electron degeneration pressure

A) interstellar dust.
B) Earth's atmosphere.
C) stars.
D) asteroids.
E) the Martian polar caps.

A) Formation of the planetary nebula
B) Fusion of hydrogen atoms into helium atoms
C) Collapse of an interstellar cloud
D) Formation of a photosphere
E) Instability in an interstellar cloud

A) Gas contains a lot of carbon atoms.
B) Dust blocks the longest electromagnetic wavelengths.
C) Gas obscures the light from distant stars.
D) We know more about the gas than the dust.
E) Dust is spread uniformly through the galaxy.

A) It first becomes opaque.
B) Density rises.
C) Temperature rises.
D) Pressure rises.
E) all of the above

A) within the last few million years.
B) about 10 million years ago.
C) hundreds of millions of years ago.
D) billions of years ago.
E) at the beginning of the universe.

A) 5,800 K
B) 100,000 K
C) 15 million K
D) 100 million K
E) One billion K

A) it is so cold it absorbs higher energy photons.
B) there is 100 times more opaque gas than dust present in the ISM.
C) the dust particles are about the same size as the light waves they absorb.
D) the dust particles are irregular in shape.
E) ice particles reflect all light back toward their stars, not toward us.

A) One star forms at its center and blows the rest of the matter back into space.
B) The cloud fragments into smaller clouds and forms many stars at one time.
C) One star forms and the rest of the matter goes into making planets, moons, and other objects of a solar system.
D) The cloud is disrupted by rotation so that it reduces its mass down to that of a typical star.
E) A supernova blows the cloud up and dissipates the majority of the gas.

A) there are no stars in these areas.
B) stars in that region are hidden by interstellar gas.
C) stars in that region are hidden by dark dust particles.
D) many brown dwarfs in those areas absorb light which they turn into heat.
E) many black holes absorb all light from those directions.

A) in molecular clouds.
B) everywhere.
C) in neutral hydrogen clouds.
D) in dark nebulae.
E) in emission nebulae.

A) Chemical combustion of hydrocarbons
B) Nuclear fusion in its core
C) From the release of gravitational energy as the protostar continues to shrink
D) The ionization of the gas as it heats up
E) From nearby hot stars or supernovae that have initiated the star formation process

A) Leftover material from their formation
B) Debris left behind by a supernova
C) Material from winds from these same stars
D) Debris left behind by passing comets
E) Star-forming molecular clouds

A) Mostly found above and below the galactic plane
B) Old age and millions of members
C) A few hundred, mainly main sequence stars
D) All stars are much more massive than our Sun.
E) All stars are about the same age and luminosity.

A) The lowest mass main sequence stars
B) The end result of massive star evolution
C) Objects that are not quite massive enough to be stars
D) Pulsars that have slowed down and stopped spinning
E) Cooled off white dwarfs that no longer glow visibly

A) it must always end up as a black hole.
B) it generates more heat and its core eventually collapses very suddenly.
C) it cannot fuse elements heavier than carbon.
D) gravity is weakened by its high luminosity.
E) it is most often found as part of a binary system.

A) about the same mass and density.
B) about the same mass and a million times higher density.
C) a larger mass and a 100 times lower density.
D) a smaller mass and half the density.
E) a smaller mass and twice the density.

A) decreases.
B) first decreases, then increases.
C) increases.
D) remains roughly constant.
E) first increases, then decreases.

A) Vertically upward, along the left edge of the diagram
B) Diagonally to lower right, then vertical, then horizontally left
C) Horizontally right, diagonally to lower left, then horizontally right
D) Horizontally right
E) Horizontally right, then forms a clockwise loop

A) No stars as hot as our Sun
B) Old age and hundreds of thousands to millions of member stars
C) No main sequence stars left, with billions of member stars
D) A few hundred stars, most still on the main sequence
E) Hundreds of light years across, with bright OB stars dominant

A) Because they can also have strong stellar winds
B) Because about half that mass will be contained in the carbon core
C) Because they would be classified as brown dwarfs
D) Because these stars will eject at least 4 solar masses in the planetary nebula stage
E) Because their masses will decrease as they fuse heavy elements into lighter elements in their cores

A) hypernova.
B) neutron star.
C) white dwarf.
D) nova.
E) black hole.

A) The bipolar jets ejected by a T Tauri variable
B) A planet surrounded by a glowing shell of gas
C) The disc of gas and dust surrounding a young star that will soon form a solar system
D) The ejected envelope, often bipolar, of a red giant surrounding a stellar core remnant
E) A type of young, medium mass star

A) Giant K- and M-type stars
B) White dwarfs
C) Dwarf K- and M-type stars
D) Main sequence O- and B-type stars
E) T Tauri stars

A) Less than a million years
B) Ten-fifty million years old
C) One to three billion years old
D) Around ten billion years old
E) A variety of ages, from newly born to twenty billion years old

A) black hole.
B) supermassive star.
C) red dwarf.
D) nebula.
E) stellar nursery.

A) Some are spherical, but most have bipolar structure.
B) They are the result of the mass loss during the main sequence stage of the most massive stars.
C) They are the rings of material surrounding newly formed stars that will eventually form the planetary systems.
D) They are the ejected envelopes of highly evolved brown dwarf stars.
E) They are the coronas surrounding most blue stragglers.

A) All stars in the cluster are the same size and luminosity.
B) Their combined light makes them much easier to spot from a distance.
C) Stars in clusters have the same age, similar composition, and are at the same distance away.
D) Stars in clusters are all relatively young and therefore shine brightly.
E) Like our Sun, stars in clusters are always located in the plane of the Milky Way Galaxy.

A) all the stars formed from the same cloud.
B) all the stars formed at about the same time.
C) all the stars are at the same distance from Earth.
D) all the stars have the same chemical composition.
E) all the stars are the same spectral type.

A) alone.
B) in intergalactic space, then were swept up into the Galaxy.
C) in clusters in the Galaxy's spiral arms.
D) from planetary nebulae.
E) in the galactic Nucleus, then migrated outward later.

A) Hypernova
B) Supernova
C) Pulsar
D) Planetary nebula
E) Nova