Deck 2: A Users Guide to the Sky

A) 2.512
B) 5
C) 8.07
D) 11.14
E) 100

A) is never above the horizon during the day.
B) always sets directly in the west.
C) is always above the northern horizon.
D) is never visible during the winter.
E) is the brightest star in the sky.

A) Greek.
B) Middle Eastern
C) Both answers (a)and (b)

A) one of the brighter stars in the sky.
B) bright enough that it would be visible even during the day.
C) not visible with the unaided eye.
D) very close to Earth.

A) 2 times fainter
B) 2 times brighter
C) 6.3 times fainter
D) 6.3 times brighter
E) 29.8 times fainter

A) ( $\alpha$ Cet)
B) ( $\alpha$ CMa)
C) Nim
D) ( $\rho$ Per)
E) ( $\delta$ Dra)

A) 18
B) (-14)
C) 3
D) (-3)
E) 5

A) ancient Arabic.
B) ancient English.
C) Latin.
D) Russian.
E) Chinese.

A) counter clockwise.
B) clockwise.
C) from left to right.
D) from right to left.
E) nearly vertically upward.

A) ( $\alpha$ Cet)
B) ( $\alpha$ CMa)
C) Nim
D) ( $\rho$ Per)
E) ( $\delta$ Dra)

A) at the same distance from the Earth.
B) at various different distances from the Earth.
C) within a boundary in the same general angular area of the sky.
D) Wrong! Constellations are made of planets only.

A) ( $\beta$ Ursa Majoris)
B) ( $\gamma$ Ursa Majoris)
C) ( $\alpha$ Ursa Majoris)
D) Wrong! Ursa Majoris is the name of the brightest star.

A) English
B) Arabic
C) Greek
D) Cyrillic

A) north celestial pole
B) south celestial pole
C) zenith
D) celestial equator
E) asterism

A) originated just after the telescope was invented.
B) can be used to indicate the apparent intensity of a celestial object.
C) is used to measure the temperature of a star.
D) was used to determine the rate of precession.

A) 73 $\degree$
B) 27 $\degree$
C) 17 $\degree$
D)5 $\degree$

A) size.
B) intensity.
C) distance.
D) color.
E) temperature.

A) 45 $\degree$
B) 23.5 $\degree$
C) 39 $\degree$
D) 51 $\degree$
E) The answer depends on the day of the year.

A) Vega must be closer to Earth than HR 4374.
B) Vega must be farther from Earth than HR 4374.
C) Vega must produce less energy than HR 4374.
D) Vega must produce more energy than HR 4374.
E) Vega will appear fainter to us than HR 4374.

A) 17 $\degree$
B) 23.5 $\degree$
C) 96.5 $\degree$
D) 73 $\degree$
E) 49.5 $\degree$

A) 90 $\degree$ N
B) 90 $\degree$ S
C) 50 $\degree$ N
D) 50 $\degree$ S
E) 0 $\degree$

A) 74 $\degree$
B) 164 $\degree$
C) 16 $\degree$
D) 5 $\degree$

A) crosses the celestial equator moving north.
B) crosses the celestial equator moving south.
C) is farthest north of the celestial equator halting its northward movement.
D) is farthest south of the celestial equator halting its southward movement.

A) straight north
B) straight east
C) straight south
D) straight west
E) straight up,directly overhead

A) 20 $\degree$ N
B) 20 $\degree$ S
C) 70 $\degree$ N
D) 70 $\degree$ S
E) 0 $\degree$

A) straight north
B) straight east
C) straight south
D) straight west
E) straight up,directly overhead

A) straight north
B) straight east
C) straight south
D) straight west
E) straight up,directly overhead

A) straight north
B) straight east
C) straight south
D) straight west
E) straight up,directly overhead

A) eastward
B) westward
C) The sun does not appear to move.

A) 52.5 $\degree$
B) 23.5 $\degree$
C) 61 $\degree$
D) 29 $\degree$
E) 5.5 $\degree$

A) farthest south of the celestial equator.
B) farthest north of the celestial equator.
C) on the celestial equator moving north.
D) on the celestial equator moving south.

A) 62 $\degree$
B) 28 $\degree$
C) 40 $\degree$
D) 5 $\degree$

A) straight north
B) straight east
C) straight south
D) straight west
E) straight up,directly overhead

A) the Earth is closer to the sun.
B) the Earth's northern hemisphere is tilted toward the sun.
C) the Earth's northern hemisphere is tilted away from the sun.

A) 90 $\degree$ N
B) 90 $\degree$ S
C) 0 $\degree$
D) 45 $\degree$ N
E) The latitude of the observer cannot be determined from the information given.

A) straight north
B) straight east
C) straight south
D) straight west
E) straight up,directly overhead

A) the earth being closer to the sun during our summer and farther during our winter
B) the sun's varying light output
C) the tilt of the earth's axis
D) the eleven-year sunspot cycle

A) 45 $\degree$
B) 23.5 $\degree$
C) 32 $\degree$
D) 58 $\degree$
E) 81.5 $\degree$

A) winter
B) summer
C) spring
D) fall

A) Only stars close to the ecliptic (the Earth's orbital plane)are located in constellations.
B) Every star is located in a constellation.
C) Only the brighter stars are in constellations.
D) Only those stars that were visible to the ancient Greeks are located in constellations.

A) No,all of the constellations are on any clear night of the year.
B) Yes.As the year progresses,the constellations move to different areas of the sky.
C) Yes,during a winter night all the constellations you can see are different from the ones that appear during a summer night.
D) Yes,during a summer night many of the constellations you can see are different from those you can see on a winter night.However,there are some constellations that are visible all year long.

A) probably formed at the same time.
B) must be part of the same cluster of stars in space.
C) must have been discovered at about the same time.
D) may actually be very far away from each other.

A) less intense
B) more intense
C) the same intensity

A) day and night
B) seasonal temperature variations
C) daily temperature variations
D) ice ages
E) the constellations

A) The nadir
B) The star Vega
C) The celestial equator
D) The north celestial pole

A) 24 hours
B) 1 year
C) 499 years
D) 41,000 years
E) Wrong! The Earth's axis tilt is fixed at exactly 23.50 with no variation whatsoever.

A) Less than one-half,because of the tilt of the equator to the ecliptic plane.
B) More than one-half,because of the precession of the poles.
C) Exactly one-half.
D) All of the night sky.

A) remain constant.
B) decrease.
C) increase.
D) Unknown unless you also state the longitude of the observer.

A) Earth's equator
B) Earth's North Pole
C) Earth's South Pole
D) any of these

A) you are at or withinlatitude of the equator.
B) you must be exactly on the equator.
C) you could be anywhere because this occurs at least once per year at any location on the Earth.

A) the night would be twice as long.
B) the night would be half as long.
C) the year would be half as long.
D) the year would be twice as long.
E) the length of the day would be unchanged

A) your horizon.
B) the Sun.
C) the Moon.
D) the fixed stars.

A) The north celestial pole
B) The summer solstice
C) The vernal equinox
D) The ecliptic pole

A) far north of Polaris.
B) far south of Polaris.
C) towards the star Vega.
D) towards the star Thuban.
E) still towards Polaris.

A) 24 hours
B) one year
C) 26 years
D) 260 years
E) 100,000 years

A) 24 hours
B) one year
C) 260 years
D) 26,000 years
E) 260,000 years

A) eastward,celestial equator
B) westward,celestial equator
C) eastward,ecliptic
D) westward,ecliptic
E) Wrong! The sun does not appear to move among the stars.

A) December.
B) March.
C) September.
D) June.

A) the force of gravity from the sun and moon on Earth's equatorial bulge.
B) the force of gravity from Neptune and Jupiter on the Earth-moon system.
C) the magnetic field of Earth.
D) the formation and subsequent melting of glaciers during the ice-ages.
E) the impact of asteroids.

A) north celestial pole
B) south celestial pole
C) celestial equator
D) horizon

A) north of overhead.
B) south of overhead.
C) through the north celestial pole.
D) through the south celestial pole.

A) straight up from the horizon
B) straight up from the horizon slanting toward the right
C) straight up from the horizon slanting toward the left
D) parallel to the horizon

A) rise in the east.
B) set in the west.
C) circle the north celestial pole counter-clockwise.
D) circle the north celestial pole clockwise.