Deck 12: Characterizing Stars

A) parallax
B) perspective
C) Doppler effect
D) inverse-square law

A) motion of the Sun around the galactic center.
B) change in latitude of the observation point on Earth.
C) motion of Earth in its orbit around the Sun.
D) rotation of Earth on its axis.

A) two centuries
B) 10 centuries
C) 22 centuries
D) 29 centuries

A) all the way to the center
B) about halfway to the center
C) about 1/80 of the way to the center
D) about 1/1000 of the way to the center

A) spectral type and surface temperature
B) rotation period
C) apparent magnitude
D) distance from Earth

A) the fourth century B.C.
B) 1721.
C) 1838.
D) 1927.

A) The changes in the observable cosmos over a human lifetime are profound.
B) A human lifetime is long enough to witness the evolution of a star through much of its evolutionary history.
C) Astronomers have never witnessed a significant change in any single star.
D) At any moment. Stars can be observed in every phase of evolution.

A) The stars appear to move periodically back and forth against the background stars because of Earth's movement around the Sun.
B) The stars appear to be extremely bright and must therefore be very close to Earth.
C) The stars are occasionally occulted or eclipsed by the Moon; hence they must be close.
D) The light from these stars shows only a very small redshift caused by the universal expansion of the universe, so they must be close.

A) the Hubble Space Telescope.
B) Friedrich Wilhelm Bessel, in 1838; no measurements since then have matched the precision of his measurements.
C) the Gaia satellite.
D) the Very Long Baseline Array of radio telescopes.

A) Sir George Airy in England
B) Henry Norris Russell in the United States
C) Tycho Brahe in Denmark
D) Friedrich Wilhelm Bessel in Germany

A) distance to an object, measured in parsecs
B) angle taken up by the size (e.g., diameter) of an object, as seen by an observer
C) shift in angular position of an object as it moves in space
D) apparent shift in position of an object as the observer moves

A) about 1/4 ly away
B) about 1/10 ly away
C) about 4 ly away
D) between 1 and 2 ly away

A) star's spectrum.
B) ratio of the star's apparent and absolute magnitudes.
C) Zeeman effect of spectral lines in the star's spectrum.
D) star's parallax.

A) Earth rotates about its own axis.
B) stars move in space.
C) stars have finite size (i.e., they are not really just points of light).
D) Earth moves in space.

A) The eyes focus back and forth continuously, and the brain interprets the focusing in terms of distance to the object viewed.
B) The eye can measure the time taken for light to travel from an object, and the brain interprets this information in terms of distance to the object viewed.
C) Humans are always moving their heads slightly from side to side, and the brain compares the angles from each of these positions to obtain the distance to the object viewed.
D) Human eyes are mounted horizontally about 10 cm apart, and the brain interprets the relative look angles of their eyes in terms of distance to the object viewed.

A) surface temperature.
B) distance from Earth.
C) apparent magnitude.
D) physical size or diameter.

A) inferred change in the distance to a star as its light is dimmed by passing through an interstellar cloud.
B) apparent shift seen in the position of a nearby star against more distant stars as Earth orbits the Sun.
C) difference between the apparent and absolute magnitudes of a star.
D) circular or elliptical motion of a star in a binary system as the two stars orbit each other.

A) between 1 and 2 pc
B) about 12 pc
C) about 4 pc
D) between 1/2 and 1 pc

A) about a hundred
B) Millions
C) None
D) only one

A) 4.24 ly
B) 0.41 ly
C) 1.33 ly
D) 0.75 ly

A) 3.26
B) 360
C) 206,265
D) 3.0 × 10⁸

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

A) 10 pc
B) 100 pc
C) 500 pc
D) 2000 pc

A) 150 arcsec
B) 1/150 arcsec
C) 1/150 degrees
D) 1/75 arcsec

A) intrinsic brightness (actual light output).
B) size (diameter).
C) temperature.
D) brightness, as seen from Earth.

A) intrinsic brightness (the total light actually emitted by the star)
B) brightness the star would appear to have if it were exactly 10 pc from Earth
C) brightness of the star as it appears in Earth's sky
D) total output of electromagnetic energy emitted at all wavelengths from the star

A) 0.0125 arcsecond.
B) 0.0125 arcminute.
C) 0.0125 radian or 0.72 $\degree$ .
D) 80 arcseconds.

A) 5.1 × 10^-3
B) 0.18
C) 5.65
D) 8.84

A) Sirius
B) Procyon
C) Vega
D) The answer to the question cannot be determined from this information alone.

A) 35 pc
B) 167 pc
C) 350 pc
D) 20 kpc

A) 10^-5 pc
B) 10⁵ light-years
C) 10 kpc
D) 100 kpc

A) 25 pc or 81.5 ly
B) 250 pc or 815 ly
C) 400 pc or 1300 ly
D) 0.004 pc or 0.013 ly

A) 500 pc
B) 200 pc
C) 0.01 pc
D) 100 pc

A) 4 pc
B) 100 pc
C) 4000 pc
D) 8000 pc

A) d = 1/p²
B) d = 1/p
C) d = p
D) d = p²

A) 2 ly
B) 1.83 ly
C) 6.52 ly
D) 3.26 ly

A) about 10 ly
B) about 33 ly
C) about 0.1 ly
D) about 3.3 ly

A) 6 arcsec
B) 20 arcsec
C) 0.02 arcsec
D) 0.05 arcsec

A) absolute magnitude.
B) apparent magnitude.
C) surface temperature.
D) luminosity.

A) 25.
B) 10.
C) 100.
D) 2.5.

A) luminosity and absolute magnitude
B) luminosity and apparent brightness
C) absolute magnitude and brightness
D) apparent magnitude and brightness

A) each magnitude (first, second, etc.) is about the same.
B) smaller magnitude numbers is much larger than the number of stars with larger magnitude numbers.
C) larger magnitude numbers is much larger than the number of stars with smaller magnitude numbers.
D) magnitudes around 3 is larger than either the number with magnitudes around 2 or the number with magnitudes around 4.

A) farther away
B) fainter
C) brighter
D) either brighter or fainter, depending on the distance to the stars,

A) fainter
B) farther away
C) brighter
D) either brighter or fainter, depending on the distance to the stars,

A) 10.
B) 1.0.
C) 0.0.
D) -1.0.

A) fainter
B) brighter
C) farther away
D) either brighter or fainter, depending on the distance to the stars,

A) tau Ceti; m = +3.49
B) alpha Centauri B; m = +1.34
C) Barnard's star; m = +9.53
D) 61 Cygni A; m = +5.21

A) either brighter or fainter, depending on the distance to the stars,
B) farther away
C) brighter
D) fainter

A) brighter, as seen in Earth's sky
B) more luminous
C) fainter, as seen in Earth's sky
D) closer to Earth

A) that Betelgeuse is brighter than Rigel.
B) that Betelgeuse is bigger than Rigel.
C) that Betelgeuse is farther away than Rigel.
D) None of these are correct.

A) be fainter than Spica (alpha Virginis), which has an apparent magnitude of +1.0.
B) be brighter than Deneb (alpha Cygni), which has an apparent magnitude of +1.2.
C) have infinite brightness since 1/0 = infinity.
D) not be emitting any light and therefore could not be seen from Earth.

A) tau Ceti; m = +3.49
B) alpha Centauri B; m = +1.34
C) Barnard's star; m = +9.53
D) 61 Cygni A; m = +5.21

A) Sirius was formed since the era in which Hipparchus lived.
B) Sirius existed during Hipparchus's lifetime, but it has obviously brightened considerably since then.
C) Hipparchus had poor eyesight and made many classification errors.
D) After using modern scientific instruments to measure the actual energy output of stars, astronomers modified the magnitude scale of Hipparchus.

A) brightness has increased.
B) surface temperature has decreased.
C) brightness has decreased.
D) surface temperature has increased.

A) about 2.5
B) 100
C) 2, by definition
D) 10

A) brighter
B) either brighter or fainter, depending on the distance to the stars,
C) farther away
D) fainter

A) farther away
B) fainter
C) either brighter or fainter, depending on the distance to the stars,
D) brighter

A) -6
B) 0
C) +6
D) +12

A) farther away
B) fainter
C) brighter
D) either brighter or fainter, depending on the distance to the stars,

A) one 0-magnitude star.
B) one star with a magnitude less than 0.
C) one star with a magnitude greater than 0.
D) two 0-magnitude stars.

A) 30
B) 30 × 2.512 = 75.4
C) (30)² = 900
D) 4 $\pi$ (30)² = 1130

A) Star B will be 1/5 as bright as star A.
B) Star B will be 1/25 as bright as star A.
C) Star B will be 1/2.2 as bright as star A.
D) Star B will be 1/20 as bright as star A.

A) star A is twice as bright as star B.
B) star B is twice as bright as star A.
C) star A is 100 times as bright as star B.
D) star B is 100 times as bright as star A.

A) 100 times brighter
B) twice as bright
C) a factor of 4/3, or 1.333 times, brighter
D) 2.512 times brighter

A) The lightbulb appears 1/16 as bright.
B) The lightbulb appears 4 times brighter.
C) The lightbulb appears 1/2 as bright.
D) The lightbulb appears 1/4 as bright.

A) 30
B) 30 * 2.512
C) 30^2.512
D) 2.512³⁰

A) Star A is brighter than Star B.
B) Star B is brighter than Star A.
C) Star A and Star B have the same brightness.
D) It is not possible to answer the question without knowing L_Sun, the luminosity of the Sun.

A) It is not possible for a star to have the same absolute and apparent magnitudes.
B) The star would have to be an infinite distance away.
C) 10 ly
D) 10 pc

A) The Andromeda Galaxy is 100 times brighter than Sirius.
B) The Andromeda Galaxy is 2 times fainter than Sirius.
C) The Andromeda Galaxy is 5 times brighter than Sirius.
D) The Andromeda Galaxy is 100 times fainter than Sirius.

A) about 2.5
B) 2
C) about 10
D) about 0.4, or 1/2.5

A) I = constant
B) I $\infty$ 1/d²
C) I $\infty$ d²
D) I $\infty$ 1/d

A) 10⁵
B) 5
C) 6
D) 100

A) 2
B) 10², or 100
C) about 2.5
D) between 6 and 7

A) 24.2 ly
B) 43.2 ly
C) 59.7 ly
D) 160.2 ly

A) watts.
B) watts per second.
C) watts per square meter.
D) parsecs.

A) 2
B) 4
C) 2.512
D) 6.310

A) 34
B) 153
C) 585
D) 1578

A) 100 times brighter
B) 5 times brighter
C) The question is incorrectly worded; the magnitude +6 star will be 100 times brighter than the magnitude +1 star.
D) 2.512 times brighter

A) The difference is +5 since absolute and apparent magnitude differ by this value by definition.
B) Apparent magnitude depends on the star's temperature, whereas absolute magnitude is independent of temperature.
C) Apparent magnitude depends on the size of the star, whereas absolute magnitude is independent of this parameter.
D) Absolute magnitude is an intrinsic property of the star, whereas apparent magnitude depends on its distance from Earth.