Deck 8: The Family of Stars

A) in the giant region.
B) in the supergiant region.
C) among the B stars.
D) among the G stars.
E) on the main sequence.

A) a supergiant star
B) a main sequence star
C) a giant star
D) a white dwarf
E) the sun

A) Alnilam
B) Antares
C) Arcturus
D) HR 5337
E) Sirius B

A) Alnilam
B) Antares
C) Arcturus
D) HR 5337
E) Sirius B

A) supergiants.
B) giants.
C) upper (more luminous) main-sequence stars.
D) white dwarfs.
E) lower (less luminous) main-sequence stars.

A) Earth's orbit was larger.
B) the stars were farther away.
C) Earth moved faster along its orbit.
D) all of these
E) none of these

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

A) is at the center of mass.
B) is farthest from the center of mass.
C) is nearest the center of mass.
D) follows the largest orbit.
E) shows a larger Doppler shift in its spectral lines.

A) distance and diameter.
B) temperature and distance.
C) distance.
D) temperature and diameter.
E) apparent magnitude.

A) brightness.
B) position on the sky.
C) wavelengths.
D) luminosity.
E) temperature.

A) Alnilam
B) Antares
C) Arcturus
D) HR 5337
E) Sirius B

A) center
B) upper left corner
C) upper right corner
D) lower left corner
E) lower right corner

A) main-sequence stars
B) giant stars
C) supergiant stars
D) white dwarfs
E) all of the above

A) they are more luminous but have about the same temperature.
B) they are less luminous but have about the same temperature.
C) they are hotter but have about the same luminosity.
D) they are cooler but have about the same luminosity.
E) they have a larger absolute magnitude than the sun.

A) color
B) apparent visual magnitude
C) luminosity class
D) spectral type
E) luminosity

A) be more luminous than a visual binary.
B) also be observed as a spectroscopic binary.
C) give off most of its light in the infrared.
D) show a constant Doppler shift in its spectral lines.
E) show two stars with variable proper motion.

A) we can't measure the radial velocities of each star in the system.
B) we can't see the shape or tilt of the orbit.
C) we can't find the diameters of the stars.
D) we can't determine the luminosities of the stars.
E) the Doppler shift is not measurable.

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

A) are most narrow for supergiants.
B) are most narrow for main-sequence stars.
C) can not be used to estimate the luminosity of the star.
D) are very weak and difficult to see.
E) are useful in determining the apparent magnitude of the star.

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

A) the ratio of the angular separation from the center of mass of each of the stars.
B) the distance to the binary and its radial velocity.
C) the semimajor axis and period of the orbit.
D) the radial velocities of the two stars.
E) the time required for the smaller star to eclipse the larger star.

A) 2 to 1
B) 1 to 2
C) 2 to 3
D) 3 to 2
E) 1 to 3

A) radial velocity.
B) proper motion.
C) brightness.
D) mass.
E) spectral type.

A) 65 Tau
B) HR 4621
C) ( $\alpha$ Pic)
D) 58 Ori
E) HR 2491

A) 2 solar masses
B) 2.5 solar masses
C) 0.5 solar mass
D) 80 solar masses
E) 0.4 solar mass

A) 2
B) 4
C) 11
D) 0.5
E) 0.25

A) ( $\delta$ Cen)
B) HR 4607
C) HR 4758
D) HD 39801
E) 9 CMa

A) 1 pc.
B) 10 pc.
C) 100 pc.
D) 1000 pc.
E) 10,000 pc.

A) 65 Tau
B) HR 4621
C) ( $\alpha$ Pic)
D) 58 Ori
E) HR 2491

A) 20 pc.
B) 50 pc.
C) 2 pc.
D) 5 pc.
E) 500 pc.

A) 65 Tau
B) HR 4621
C) ( $\alpha$ Pic)
D) 58 Ori
E) HR 2491

A) Star A is twice the mass of star B.
B) Star B is twice the mass of star A.
C) Star A is ten times the mass of star B.
D) Star B is ten times the mass of star A.
E) Star A and Star B have the same mass.

A) 65 Tau
B) HR 4621
C) ( $\alpha$ Pic)
D) 58 Ori
E) HR 2491

A) ( $\delta$ Cen)
B) HR 4607
C) HR 4758
D) HD 39801
E) 9 CMa

A) Star A has a mass of 1 solar mass and star B has a mass of 6 solar masses.
B) Star A has a mass of 20 solar mass and star B has a mass of 6 solar masses.
C) Star A has a mass of 31.2 solar mass and star B has a mass of 5.2 solar masses.
D) Star A has a mass of 22.3 solar mass and star B has a mass of 3.7 solar masses.
E) The masses of star A and star B cannot be determined from the information given.

A) 65 Tau
B) HR 4621
C) ( $\alpha$ Pic)
D) 58 Ori
E) HR 2491

A) ( $\delta$ Cen)
B) HR 4607
C) HR 4758
D) HD 39801
E) 9 CMa

A) 175,000 km
B) 350,000 km
C) 194 km
D) 700,000 km
E) 4656 km

A) 5 days
B) 32.5 days
C) 7.5 days
D) 42.5 days
E) 50 days

A) cooler
B) brighter as seen from Earth
C) larger
D) smaller
E) more massive

A) closer than 10 pc.
B) farther than 10 pc.
C) No way to tell.

A) ( $\alpha$ For; F8)
B) (o Cet; M7)
C) 35 Ari; B3
D) ( $\gamma$ Tri; A0)
E) (F Per; O7)

A) Lyman series.
B) Balmer series.
C) Paschen series.
D) isotopes of hydrogen.
E) ions of hydrogen.

A) by combining the apparent magnitude with the star's parallax
B) by measuring the period of variability in the star's apparent magnitude
C) by studying the absorption line width in the spectrum of the star
D) by observing the angular size of the star's image in a photograph or digital image

A) TiO molecules.
B) ionized helium.
C) helium.
D) hydrogen.
E) all of the above.

A) ( $\alpha$ For; F8)
B) (o Cet; M7)
C) 35 Ari; B3
D) ( $\gamma$ Tri; A0)
E) ( Per; O7)

A) stars of high luminosity
B) stars of low luminosity
C) nearby stars
D) distant stars
E) not enough information given

A) Lyman series.
B) Balmer series.
C) Paschen series.
D) isotopes of hydrogen.
E) ions of hydrogen.

A) the pattern of absorption lines from various atoms.
B) the relative intensities of light measured through different photometric filters.
C) the peak wavelength of the star's continuous blackbody spectrum.
D) pattern of emission lines that are on the star's spectrum.

A) There is no hydrogen in stars this cool.
B) The stars are hot enough that most of the hydrogen is ionized and the atoms cannot absorb energy.
C) These stars are so cool that nearly all of the hydrogen atoms are in the ground state.
D) Stars of this temperature are too cool to produce an absorption spectrum.
E) Stars of this temperature are too hot to produce an absorption spectrum.

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

A) distance and diameter.
B) temperature and distance.
C) distance.
D) temperature and diameter.
E) apparent magnitude.

A) Some stars are occasionally eclipsed by the moon, so they must be nearby.
B) Some stars vary in brightness caused by sunspots we can see because they are so close.
C) Some stars appear to be extremely bright and must therefore be very close to us.
D) Some stars appear to move periodically back and forth against the background stars because of Earth's movement around the sun.

A) By continuously focusing our eyes on distant objects, we can determine distance.
B) Since our eyes are separated, the brain interprets the relative look angles of these eyes in terms of distance to the object viewed.
C) Our eyes can measure the time it takes light to travel from an object and from this we get distance.
D) By moving our heads from side to side our brain compares look angles from each of these positions to obtain the distance to the object viewed.

A) There is no hydrogen in stars this hot.
B) The stars are hot enough that most of the hydrogen is ionized and the atoms cannot absorb energy.
C) These stars are so cool that nearly all of the electrons in the hydrogen atom are in the ground state.
D) Stars of this temperature are too cool to produce an absorption spectrum.
E) Stars of this temperature are too hot to produce an absorption spectrum.

A) the one with the larger radius will always have the greater luminosity.
B) the one with the higher surface temperature will always have the greater luminosity.
C) the one with the smaller absolute magnitude will always have the greater luminosity.
D) the one with the larger surface area has the greater energy flux from its surface.

A) Lyman series.
B) Balmer series.
C) Paschen series.
D) isotopes of hydrogen.
E) ions of hydrogen.

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

A) brighter.
B) dimmer.
C) redder.
D) bluer.
E) They will have the same brightness as seen from Earth.

A) I & II
B) II & IV
C) I & IV
D) I & III
E) II & III

A) the stars are in an elliptical orbit around one another.
B) the mass of the pair can be estimated.
C) one star is passing by the other never to return.
D) both A and B

A) radius.
B) temperature.
C) mass.
D) distance.
E) all of the above.

A) how bright it appears to us if it is at its actual distance.
B) how bright it appears to us at a standard distance of 10 pc.
C) its energy output per second compared to the sun.
D) its mass in solar masses.
E) its surface temperature in Kelvin.

A) the masses
B) the sizes
C) both a and b
D) neither a nor b

A) sound echoes knowing the speed of sound and time
B) parallax using Earth's orbit
C) human binocular vision
D) Balmer series
E) none of the above

A) upper main-sequence stars.
B) white dwarfs.
C) lower main-sequence stars.

A) the time in years for them to orbit one another.
B) the size of their orbit.
C) their apparent magnitudes.
D) both A and B

A) stars that appear brightest in the sky to an observer on Earth.
B) all of the stars within our solar system.
C) all the stars within a given distance from Earth.

A) being seen as two separate stars with a telescope.
B) one star traveling a wiggly proper-motion path across the sky.
C) one star dimming abruptly as another passes in front of it.
D) pairs of absorption lines seen in the spectrum of what appears to be one star.
E) all of the above.

A) 1 solar masses
B) 2 solar masses
C) 4 solar masses
D) 8 solar masses
E) 16 solar masses

A) of its measured color.
B) of its measured temperature compared to Sirius A.
C) it is part of binary star system with Sirius A.

A) the masses
B) the sizes
C) both a and b
D) neither a nor b