Deck 7: The Structure and Formation of Stars

A)Luminosity depends on mass.
B)Pressure depends on temperature.
C)Density depends on mass.
D)Weight depends on temperature.

A)a Herbig-Haro object
B)a reflection nebula made of dust
C)young low-mass stars
D)an emission nebula made of gas

A)T Tauri stars
B)Bok globules
C)O associations
D)Herbig-Haro objects

A)Carbon nuclei are split 3 ways to make helium nuclei.
B)Carbon and oxygen combine to form nitrogen, which produces energy.
C)Carbon and nitrogen combine to form oxygen and energy.
D)Four hydrogen nuclei combine to form one helium nucleus and energy.

A)HI regions
B)HII regions
C)Bok globules
D)HeI regions

A)1%
B)10%
C)20%
D)90%

A)the balance between the pressure and force of gravity inside a star
B)the force that binds protons and neutrons together to form a nucleus
C)the temperature and density at which a gas will undergo thermonuclear fusion
D)a measure of the resistance to the flow of radiation (photons) through a gas

A)The Orion Nebula contains large amounts of gas and dust.
B)Massive stars have short lives, so they must have formed recently.
C)Massive stars trigger star formation in nearby gas clouds.
D)The Orion Nebula contains large numbers of brown dwarfs and supernova remnants.

A)Two protons are fused to make a helium nucleus.
B)Three protons are fused to make a lithium nucleus.
C)A helium nucleus is split into four protons.
D)Four protons are fused to make a helium nucleus.

A)the rapid outward flow of gas
B)the rapid inward flow of gas
C)the high temperature and density of the gas
D)the low mass of helium nuclei

A)the zero-age main sequence
B)the birth line
C)the Coulomb barrier
D)the evolutionary track

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

A)if they encounter a shock wave
B)if they have very high temperatures
C)if they rotate rapidly
D)if they are located near main-sequence spectral type K and M stars

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

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

A)The protostar stage is very long.
B)They are all so far away that the light hasn't reached us yet.
C)Most of their radiation is in the form of X-rays.
D)They are surrounded by cocoons of gas and dust.

A)because it mixes the star's gases and increases the temperature of the star
B)because it mixes the star's gases and transports energy outwards
C)because it carries energy toward the core of the star
D)because it carries the neutrinos to the surface of the star where they can escape

A)the CNO cycle
B)the proton-proton chain
C)hydrostatic equilibrium
D)the neutrino process

A)brown dwarfs
B)Herbig-Haro objects
C)Bok globules
D)T Tauri stars

A)A protoplanetary disk forms.
B)The star stops collapsing.
C)The T Tauri phenomenon occurs.
D)Jets extend into the interstellar medium.

A)high mass stars that have not reached the main sequence yet
B)low mass stars that have not reached the main sequence yet
C)mainly giant stars, since most stars have left the main sequence
D)no stars, since none have reached the main sequence yet

A)0.08 solar mass
B)1 solar mass
C)8 solar masses
D)80 solar masses

A)100,000 K
B)10,000 K
C)1000 K
D)100 K

A)nuclear fusion
B)nuclear fission
C)gravitational potential energy
D)magnetic fields

A)3.2×10⁷ years
B)1×10⁹ years
C)1×10¹¹ years
D)3.2×10¹² years

A)nuclear fusion
B)nuclear fission
C)gravitational potential energy
D)magnetic fields

A)1.8×10⁶ years
B)1.8×10⁹ years
C)1.8×10¹⁰ yearsα
D)1.8×10¹¹ years

A)The lines are blue shifted.
B)The lines are red shifted.
C)The lines are extremely broad.
D)The lines are extremely narrow.

A)brighter and cooler than it really is
B)brighter and hotter than it really is
C)fainter and cooler than it really is
D)fainter and hotter than it really is

A)because helium fusion produces carbon
B)because more massive stars support their larger weight by making more energy
C)because the helium flash occurs in degenerate matter
D)because all stars on the main sequence have about the same radius

A)by using infrared telescopes to detect ionized gas in the clouds
B)by using X-ray telescopes to observe the X-ray radiation from the molecules in the cloud
C)by using radio telescopes to observe the emission from CO molecules in the clouds
D)by using radio telescopes to observe the 21-cm radiation from hydrogen

A)extinction of light from distant stars
B)very narrow calcium absorption lines in the spectra of O and B stars
C)reddening of more distant stars
D)molecular absorption lines in the spectra of cool stars

A)0.01 solar masses
B)0.1 solar masses
C)1.1 solar masses
D)11 solar masses

A)HII regions
B)emission nebulae
C)Bok globules
D)reflection nebulae

A)emission nebulae
B)HI regions
C)molecular clouds
D)21-centimetre radiation

A)dust particles
B)ionized hydrogen
C)neutral hydrogen
D)molecular gas

A)They are wider than the lines from stars because the gas is hotter than most stars.
B)They are narrower than the lines from stars because the gas has a lower pressure than stars.
C)They indicate that the interstellar medium contains different elements than stars do.
D)They indicate that interstellar medium clouds have high velocities.

A)reflection nebulae
B)dense molecular clouds
C)HII regions
D)the intercloud medium

A)Low mass stars form from the interstellar medium very rarely.
B)Low mass objects are composed primarily of solids, not gases.
C)The lower limit represents a star with zero radius.
D)A minimum temperature is required for hydrogen nuclear fusion to take place.

A)They showed that the "missing neutrinos" had changed into a different type.
B)They showed that other experiments had mis-counted the number of solar neutrinos.
C)They showed that models for the number of neutrinos produced by the Sun were wrong.
D)They showed that neutrinos were not escaping from the core of the Sun.

A)Higher mass stars burn through their nuclear fuel faster.
B)Lower mass stars don't get their energy from nuclear fusion like higher mass stars do.
C)Higher mass stars have less hydrogen fuel to burn.
D)Lower mass stars spend a longer time evolving to the main sequence.

A)density and composition
B)density and the presence of dust
C)temperature and the presence of dust
D)temperature and luminosity

A)High temperatures increase the ground state energy of the hydrogen atom.
B)High temperatures increase the velocity of the protons so they can overcome the Coulomb barrier.
C)High temperatures lower the density of the gas.
D)High temperatures allow the neutrinos to carry more energy away than the reaction produces.

A)ultraviolet radiation emitted by dust
B)narrow emission lines seen in stellar spectra
C)the presence of bright nebulae
D)the blue colour of stars seen near dark regions

A)Hydrostatic equilibrium ends.
B)Nuclear fusion reactions in the core begin.
C)Helium flash occurs in the core.
D)Gravitational contraction begins.

A)Your feet are warmed when you hold them in front of a fire.
B)Your feet are warmed when you wear socks.
C)Your feet get cold when you stand on a cold floor.
D)Your feet get cold when you hold them over a cool air vent.

A)temperature
B)mass
C)age
D)luminosity

A)nuclear fission
B)nuclear fusion
C)convection
D)radiation

A)nuclear
B)gravity
C)electric
D)magnetic

A)The equations apply the laws of stellar structure at locations within the star.
B)Equations can describe the H-R diagram and a star's location on it.
C)The mass-luminosity equation tells you how to find a star's luminosity given its mass.
D)Equations are used to model the nuclear reactions inside a star.

A)Star 2 has more helium in its core and a hotter surface.
B)Star 2 has more helium in its core and a cooler surface.
C)Star 1 is more luminous and has a hotter surface.
D)Star 1 is more luminous and has a cooler surface.

A)The radiation rate depends on temperature.
B)The dependence of opacity on temperature makes convection happen.
C)The dependence of opacity on temperature makes conduction happen.
D)The temperature determines how much energy is produced at each layer.

A)The magnetic fields are strongest there.
B)The temperature and density are highest in the centre.
C)The core is the only place where hydrogen is found.
D)The strong nuclear force is only active in the centres of stars.

A)transmission
B)emission
C)reflection
D)absorption

A)two hydrogen nuclei, a single helium nucleus and energy in the form of visible light
B)four hydrogen nuclei and energy in the form of gamma rays
C)a helium nucleus and energy in the form of gamma rays
D)two hydrogen nuclei and energy in the form of visible light

A)O, A, K, M
B)A, B, F, G
C)K, F, B, O
D)B, A, M, G

A)proton-proton chain energy
B)Coulomb barrier energy
C)strong force energy
D)nuclear binding energy

A)age
B)distance from the galactic centre
C)mass
D)radius

A)The Sun is fusing helium but not hydrogen.
B)Nuclear reactions do not produce neutrinos as fast as theory predicts.
C)The Sun may contain matter we haven't yet identified.
D)Neutrinos may oscillate between three different flavours.

A)It binds electrons to the nucleus in an atom.
B)It holds the Moon in orbit around the Earth.
C)It creates the magnetic field associated with sunspots.
D)It binds protons and neutrons together to form a nucleus.

A)Young stars have not moved far from the gaseous nebulae where they were born.
B)Only hot stars can ionize nearby gas; hot stars are high-mass, so must be young.
C)The dust that makes emission nebulae glow is destroyed by old stars.
D)Young stars produce the blue light that is scattered by emission nebulae.

A)the planet Jupiter
B)a red dwarf
C)a white dwarf
D)a Bok globule

A)a globular cluster
B)an open cluster
C)an association
D)a spherical component