Deck 5: Sun Light and Sun Atoms

A)1
B)2
C)3

A)nitrogen and oxygen
B)hydrogen and helium
C)carbon and hydrogen
D)carbon and nitrogen

A)As the train approaches, the horn will sound lower in pitch than when the train is moving away.
B)As the train approaches, the horn will sound higher in pitch than when the train is moving away.
C)As the train approaches, the headlight will appear bluer than when the train is moving away.
D)As the train approaches, the headlight will appear redder than when the train is moving away.

A)heat
B)composition
C)temperature
D)binding energy

A)These stars are so hot that most of the hydrogen is ionized and the atoms cannot absorb energy.
B)These stars are so cool that nearly all of the electrons in the hydrogen atom are in the ground state.
C)Stars of this temperature are too cool to produce an absorption spectrum.
D)Stars of this temperature are too hot to produce an absorption spectrum.

A)ionized
B)excited
C)ground
D)isotopic

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

A)ionization
B)Doppler broadening
C)collisional broadening
D)a red shift

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

A)1
B)2
C)3

A)nucleus
B)ion
C)proton
D)molecule

A)1
B)2
C)3

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

A)one proton and one neutron
B)one proton
C)one proton, one neutron, and one electron
D)one proton and one electron

A)zero degrees Celsius
B)the temperature at which no thermal energy can be extracted from atoms
C)the temperature at which water freezes
D)the temperature at which molecules split into atoms

A)the speed at which a star is moving away from an observer
B)the apparent velocity of a star across the sky
C)the radial velocity of a star
D)the speed at which a car is travelling toward an observer

A)These stars are so hot that most of the hydrogen is ionized and the atoms cannot absorb energy.
B)These stars are so cool that nearly all of the electrons in the hydrogen atom are in the ground state.
C)Stars of this temperature are too cool to produce an absorption spectrum.
D)Stars of this temperature are too hot to produce an absorption spectrum.

A)emitting a photon
B)colliding with another atom or electron
C)reflecting a photon
D)gaining an extra electron

A)the absolute zero temperature
B)the ground state
C)the ionization level
D)the energy level from which the Paschen series of hydrogen originates

A)3.5×10⁻³⁶ J
B)6.0×10⁻¹⁹ J
C)3.5×10⁻¹⁸ J
D)6.0 ×10⁻¹⁸ J

A)Kirchhoff's law
B)Wien's law
C)Coulomb force
D)Balmer series

A)the same number of protons and neutrons
B)the same number of protons and electrons
C)twice as many protons as neutrons
D)twice as many neutrons as protons

A)by using the density of hydrogen as measured on Earth
B)by analysing samples of the solar wind
C)by using the amount of area covered by Venus during a transit
D)by using Newton's laws and the Sun's diameter

A)Kirchhoff's law
B)the Coulomb force
C)quantum mechanics
D)the binding energy

A)No, because the red star has a lower temperature.
B)Yes, if the red star has a larger area.
C)Yes, if the red star has a larger wavelength of maximum intensity.
D)No, because red stars are less massive than blue stars.

A)5 times
B)25 times
C)625 times
D)1.3×10¹⁵ times

A)red, yellow, blue
B)red, blue, yellow
C)yellow, red, blue
D)blue, yellow, red

A)0 Kelvin
B)100 Kelvin
C)0° Celsius
D)100° Celsius

A)The temperature of each element varies.
B)Elements can exist in different forms of matter.
C)Electron energy levels differ for each element.
D)Each element has a different mass.

A)a neutron
B)an electron
C)a molecule
D)a nucleus

A)distance
B)core temperature
C)rotational velocity
D)velocity across the sky

A)Lyman series
B)Balmer series
C)Paschen series
D)Brackett series

A)less than 434 nm
B)434.0 nm
C)greater than 434 nm
D)the wavelength depends on the composition of the star

A)The atom is ionized.
B)The atom is dissociated.
C)The atom is excited.
D)The atom is neutralized.

A)ions
B)molecules
C)nuclear pairs
D)isotopes

A)1040 K
B)2900 K
C)5800 K
D)10400 K

A)The star is moving away from the observer.
B)The star is moving toward the observer.
C)The star is moving but the direction is not known.
D)The star is not moving toward or away from the observer.

A)The ionized gas in the photosphere emits a continuous spectrum, which the chromosphere changes into an absorption spectrum.
B)The ionized gas in the photosphere emits an absorption spectrum.
C)The Sun's photosphere is cooler than the layers below it.
D)The Sun's photosphere is hotter than the layers below it.

A)260 nm
B)1040 nm
C)5800 nm
D)11600 nm

A)Regions of the photosphere are obscured by material in the chromosphere.
B)Shock waves move through the photosphere.
C)The strong magnetic field inhibits the currents of hot gas rising from below.
D)They radiate their energy into space faster than the rest of the photosphere.

A)Heating in the chromosphere and corona makes them hotter than the photosphere.
B)A magnetic dynamo operates inside the Sun.
C)The equatorial regions of the Sun rotate more rapidly than the polar regions.
D)The rotation of the Sun's southern and northern hemispheres goes in opposite directions.

A)sunspots
B)rising and sinking gases below the photosphere
C)shock waves in the corona
D)the solar wind flowing away from the corona

A)shock waves rising from below the photosphere
B)the solar wind
C)sunspots
D)high energy particles being accelerated by the Sun's magnetic field

A)Maunder sunspot minimum
B)Babcock sunspot model
C)coronal hole
D)weak solar force

A)the longitude at which most sunspots occur
B)the number of sunspots that are visible
C)the rotation rate of the Sun's equator
D)the temperature of sunspot cores

A)solar flares
B)sunspots
C)granules
D)prominences

A)at the solar equator, in the lowest levels of the photosphere
B)at the centres of sunspots
C)in the corona near the north and south poles of the Sun during a total solar eclipse
D)in filtergrams of the solar chromosphere

A)Doppler shifts in spectral lines are observed.
B)The Zeeman effect is observed in sunspots.
C)Collisional broadening is observed in spectral lines.
D)Infrared observations indicate that the sunspots are cooler than their surroundings.

A)500 K
B)900 K
C)5,000 K
D)9,000 K

A)a wide band of wavelengths in the infrared
B)a wide band of wavelengths in the ultraviolet
C)a narrow band of Zeeman effect wavelengths
D)a narrow band of wavelengths in a specific spectral line

A)the chromosphere
B)the photosphere
C)the corona
D)the sunspots

A)prominences
B)coronal holes
C)granulation
D)auroras

A)400 km
B)1,000 km
C)2,300 km
D)2,500 km to 4,000 km

A)helioseismology
B)neutrino detectors
C)a magnetic carpet
D)the Zeeman effect

A)cooler than the photosphere
B)is below the corona
C)is above the visible surface of the Sun
D)produces an emission spectrum

A)It shifts the wavelength of spectral lines.
B)It changes the speed of light emitted from the object.
C)It makes the object appear hotter.
D)It makes the object appear cooler.

A)hot material rising to the photosphere from below
B)cool material falling from the photosphere to the regions below
C)material that is fainter and hotter than its surroundings
D)material that is brighter and cooler than its surroundings.

A)dynamo effect
B)Zeeman effect
C)Babcock effect
D)aurora

A)coronas
B)flares
C)auroras
D)coronal holes

A)This temperature is so low that a human would freeze to death.
B)This is a Canadian winter temperature; humans could survive with a winter jacket and boots.
C)This is a Canadian summer temperature; humans could be comfortable in shorts and a T-shirt.
D)This temperature is so high that a human would die of heatstroke.

A)fastest at the equator, slower at mid-latitudes, and slowest near the poles
B)slowest at the equator, faster at mid-latitudes, and fastest near the poles
C)fastest at the equator, and slowest at mid-latitudes and the poles, which travel at the same speed
D)the same regardless of latitude

A)The photosphere is less than 500 km deep.
B)The photosphere is made of hydrogen gas.
C)The photosphere has a very low temperature.
D)The photosphere has a very low density.

A)500 km
B)1,000 km
C)2,300 km
D)2,500 km to 4000 km

A)the height of the Sun's corona
B)the strength of the solar wind
C)magnetic fields of sunspots
D)vibrations on the Sun's surface

A)solar flare
B)supergranule
C)spicule
D)coronal hole

A)Gas moves upward in the centres of some cells and downward in others; the gas cools as it passes between individual granules.
B)The gas is actually motionless. The dark regions are absorption features from gases in the photosphere.
C)Gas moves upward in the bright cell centres and downward around the darker edges.
D)Gas moves downward in the bright cell centres and upward around the darker edges.

A)2010
B)2012
C)2018
D)2023

A)15 to 30 degrees north and south of the Sun's equator
B)evenly distributed over the Sun's surface
C)near the Sun's equator
D)near the poles of the Sun (latitudes 90° north and south)

A)temperature and density both decrease
B)temperature decreases and density increases
C)temperature increases and density decreases
D)temperature and density both increase

A)4×10⁻⁷ years
B)about 2 years
C)250 years
D)2,500,000 years

A)spicules
B)prominences
C)supergranules
D)solar wind

A)Sunspots are holes in the photosphere that reveal the lower-temperature gases in the deeper layers.
B)Sunspots represent points where streams of cool gas from the corona lower the temperature in those regions of the photosphere.
C)Powerful magnetic fields in the sunspots act upon the atoms of the photosphere to prevent them from emitting light.
D)Powerful magnetic fields in the sunspots inhibit the convective flow of the gases of the photosphere downward, allowing the area to cool for longer than would normally be possible.

A)corona, chromosphere, photosphere
B)photosphere, corona, chromosphere
C)photosphere, chromosphere, corona
D)chromosphere, photosphere, corona

A)the full Moon
B)a gas stove
C)a neon sign
D)an incandescent light bulb

A)The granules form the base of a circulation pattern that extends from the photosphere to the outer corona.
B)The granules are regions of nuclear energy generation in the Sun's photosphere.
C)Each granule contains a strong magnetic field, which compresses and heats the gas underneath it.
D)The granules are the tops of hot gases that have risen from the Sun's convective zone.

A)the Balmer series
B)dynamo effects
C)the Zeeman effect
D)isotope ratios

A)She was the first person to show that the Sun is mostly hydrogen.
B)She was the first person to analyze spectra of stars.
C)Her analysis of stellar spectra showed that stars generate their own light.
D)Her analysis of the Sun's spectrum resulted in the discovery of helium.

A)during a lunar eclipse
B)with a coronagraph
C)using filtergrams
D)using the Zeeman effect

A)A star appears to have a much higher temperature when moving toward the Earth than when moving away.
B)An ambulance's siren changes to a higher pitch as it speeds toward you.
C)A star's colour becomes redder as it moves away from the Earth.
D)A moving train's whistle shifts to a frequency so high that humans can't hear it.