Deck 15: Star Formation and the Interstellar Medium

A) the object appears dimmer
B) the object appears bluer
C) the object appears bluer and dimmer
D) the object appears redder and dimmer
E) the object's apparent velocity changes

A) 1 atom/cm³
B) 1,000 atom/cm³
C) 10⁴ atom/cm³
D) 10⁶ atom/cm³
E) 10¹² atom/cm³

A) dust grains
B) cold gas
C) hot gas
D) warm gas

A) Nothing; it is empty.
B) spacecraft
C) gas
D) dark matter
E) none of the above

A) interstellar dust is dark at optical wavelengths, but bright in the infrared
B) supernovae can heat their shells to such high temperatures
C) an astronaut would feel cold standing in the 10⁶ K intercloud gas
D) the Solar System is immersed in a hot bubble of gas
E) fusion only occurs in the cores of stars

A) It is a region where there are no stars.
B) It is a region with lots of dark matter.
C) It is a super-massive black hole.
D) It is a region with thick dust blocking the starlight coming from behind.
E) It is a dark star cluster.

A) hydrogen gas, condensed out of the interstellar medium, like water clouds in the Earth's atmosphere
B) regions where hydrogen tends to be denser than the surrounding gas
C) regions where water condenses out of the interstellar medium
D) oxygen gas, condensed out of the interstellar medium, like water clouds in the Earth's atmosphere
E) regions where hydrogen combines with oxygen to create water molecules

A) only by supernovae
B) by supernovae and strong winds from luminous stars
C) by supernovae, strong winds from luminous stars, and fast-moving stars
D) by supernovae, strong winds from luminous stars, fast-moving stars, and exploding planets
E) by supernovae, strong winds from luminous stars, fast-moving stars, exploding planets, and black holes

A) carbon monoxide (CO)
B) warm, neutral hydrogen
C) molecular hydrogen (H₂)
D) ionized hydrogen (H II region)
E) dust

A) it re-emits the light it absorbs at red wavelengths
B) it emits mostly in the infrared due to its cold temperature
C) it is made mostly of hydrogen, which produces the red H-alpha emission line
D) it preferentially affects light at visible and shorter wavelengths
E) it primarily moves away from Earth

A) newly formed stars
B) young stars
C) ionized hydrogen gas
D) O- and B-type stars
E) all of the above

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

A) 1 $\mu$ m
B) 30 $\mu$ m
C) 50 $\mu$ m
D) 100 $\mu$ m
E) 500 $\mu$ m

A) red
B) yellow
C) white
D) blue
E) dark

A) H-alpha emission to look for O and B stars
B) 21 cm radiation to find neutral hydrogen clouds
C) radio emission from carbon monoxide (CO) to find molecular cloud cores
D) infrared emission to identify T Tauri stars
E) all of the above

A) high-energy radiation from stars
B) supernovae
C) young O and B stars
D) planetary nebulae
E) The heating is an even mix of all of the sources above.

A) I, II, III
B) II, III, I
C) I, III, II
D) II, I, III
E) III, I, II

A) expand
B) contract
C) implode
D) remain the same size
E) explode

A) low temperatures
B) high densities
C) lots of dust
D) all of the above

A) 0.3 K
B) 10 K
C) 80 K
D) 300 K
E) 1000 K

A) protostars
B) Herbig-Haro objects
C) molecular hydrogen (H₂)
D) carbon monoxide (CO)
E) all of the above

A) visible; ultraviolet
B) infrared; radio
C) infrared; visible
D) radio; ultraviolet
E) visible; infrared

A) an electron moves from the n = 1 to n = 2 state in a hydrogen atom
B) an electron is ionized from a hydrogen atom
C) carbon monoxide (CO) gas is excited by stellar radiation
D) the spin of an electron flips and aligns with the spin of a proton in a hydrogen atom
E) an electron combines with a proton to make a hydrogen atom

A) X-ray
B) ultraviolet
C) optical
D) infrared
E) radio

A) magnetic fields
B) conservation of angular momentum
C) pressure
D) gravity
E) turbulence

A) decreases because it is radiating
B) decreases because of gravitational contraction
C) decreases because of angular momentum
D) increases because of nuclear fusion
E) increases due to the kinetic energy of infalling material

A) heat and rotation
B) core temperature and surface temperature
C) pressure and gravity
D) radiation and heat
E) luminosity and distance

A) density
B) luminosity
C) age
D) temperature
E) radius

A) Its density rises.
B) Its temperature rises.
C) Its radius decreases.
D) Its pressure rises.
E) All of the above are true.

A) less luminous; hotter
B) larger; cooler
C) smaller; the same
D) more luminous; cooler
E) smaller; hotter

A) spin slower
B) spin faster
C) increase in temperature
D) decrease in temperature
E) stay the same temperature

A) only how the protostar's radius changes with time
B) how the protostar's luminosity, temperature, and radius change with time
C) only how the protostar's luminosity changes with time
D) only how the protostar's spectral type changes with time
E) the protostar's location in the molecular cloud

A) Planets form in the accretion disk.
B) The star grows suddenly larger in radius.
C) Triple alpha reactions begin in the core.
D) Nuclear fusion begins in the core.
E) Convection begins throughout the star's interior.

A) they never reach masses larger than 50 Jupiter masses
B) hydrogen fusion never begins in their cores
C) convection never plays a role in their energy transport
D) they primarily shine at infrared wavelengths
E) they are never as luminous as the Sun

A) inhibit gravitational collapse
B) fragment the cloud into numerous cores
C) modulate the temperature of the molecules
D) increase the formation of dust grains
E) increase the formation of protostars

A) They occur in dusty regions.
B) They have low luminosities.
C) They do not shine at any wavelength until they become T Tauri stars.
D) The star formation process happens so quickly.
E) They are too small to be seen.

A) black hole
B) brown dwarf
C) Herbig-Haro object
D) protostar
E) T Tauri star

A) hotter
B) rotating faster
C) smaller
D) denser
E) more luminous

A) do not have strong enough gravity to form planets
B) have much higher temperatures than the Sun
C) cannot successfully execute the proton-proton chain reactions
D) form much faster than the Sun did
E) do not exhibit sunspots

A) temperature; luminosity
B) radius; temperature
C) luminosity; radius
D) luminosity; temperature
E) radius; luminosity

A) high mass
B) high temperature
C) turbulence
D) magnetic fields
E) angular momentum

A) reacts with oxygen to produce water
B) undergoes fusion and produces energy
C) helps make the protostars denser
D) acts as a temperature regulator
E) reduces angular momentum

A) energy
B) centrifugal force
C) gravity
D) velocity
E) angular momentum

A) thermonuclear energy
B) kinetic energy
C) chemical energy
D) gravitational potential energy
E) radiation energy

A) the luminosity decreases
B) the luminosity increases
C) the temperature increases
D) the temperature decreases
E) either the luminosity decreases or the temperature increases

A) temperature; luminosity
B) radius; temperature
C) luminosity; radius
D) luminosity; temperature
E) radius; luminosity

A) high-mass stars
B) low-mass stars
C) an equal mix of high- and low-mass stars
D) low-mass stars near the Sun and high-mass stars far away
E) We do not yet know which types of stars are most common in our galaxy.

A) 25 R _$\odot$
B) 55 R _$\odot$
C) 75 R _$\odot$
D) 105 R _$\odot$
E) 125 R _$\odot$

A) 10 M _$\odot$
B) 50 M _$\odot$
C) 100 M _$\odot$
D) 500 M _$\odot$
E) 1,000 M _$\odot$

A) 10 times bigger than
B) 100 times bigger than
C) 10 times smaller than
D) 100 time smaller than
E) the same as

A) 100 M _$\odot$ stars
B) 10 M _$\odot$ stars
C) 1 M _$\odot$ stars
D) 0.1 M _$\odot$ stars
E) 0.08 M _$\odot$ stars

A) 3 * 10⁷ years
B) 3 *10⁵ years
C) 3,000 years
D) 300 years
E) 30 years

A) in our Solar System
B) orbiting stars other than the Sun
C) orbiting stars in binary systems
D) traveling on their own through the Milky Way, not orbiting a star
E) all of the above