Deck 8: The Sun

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

A) 1 AU
B) 2 AU
C) 5 AU
D) 10 AU
E) 20 AU

A) chromosphere → corona → photosphere
B) corona → chromosphere → photosphere
C) chromosphere → photosphere → corona
D) photosphere → chromosphere → corona
E) photosphere → corona → chromosphere

A) 5000 ^o C
B) 5800^oC
C) 5800 K
D) 6400 K
E) 10,000^oC

A) sunspots
B) spicules
C) granules
D) flares
E) CMEs

A) sunspots
B) magnetic fields
C) supergranules
D) limb darkening
E) Doppler shifts

A) reversal in rotation of the Sun
B) little to no sunspot activity
C) decreased temperature of the photosphere
D) partial dissipation of the corona
E) little to no solar wind

A) one
B) two
C) three
D) four
E) five

A) reconnection events; flares
B) supergranules; Coulumb barriers
C) filaments; coronal holes
D) solar winds; convective zones
E) prominences; limb darkening

A) timed a full rotation of the Sun's equator
B) observed sunspots move across the surface of the Sun
C) measured different spectral lines of emission on different days
D) noted how the Sun rose in the east and set in the west
E) discovered the parallax of the Sun

A) convection
B) solar cycle
C) magnetic fields
D) bursts of energy
E) differential rotation

A) Zeeman effect
B) Maunder effect
C) Babcock effect
D) Galileo effect
E) Payne effect

A) Atoms within the corona become more ionized at higher altitudes.
B) Atoms are forced upward from the chromosphere to the corona.
C) Atoms become neutralized as they dissipate in higher altitudes.
D) Atoms undergo fission when repelled by the corona.
E) Atoms are less excited as they move from the photosphere to the corona.

A) 7 years
B) 11 years
C) 22 years
D) 40 years
E) 100 years

A) blue, green, and yellow
B) red, blue, and violet
C) green, blue, and violet
D) red, magenta, and violet
E) indigo, blue, and red

A) solar cycle
B) sunspot cycle
C) convection currents
D) magnetic field shifts
E) differential rotation

A) magnetic carpet
B) chromosphere
C) heliosphere
D) solar wind
E) corona

A) 5800 K
B) 10,000 K
C) 500,000 K
D) 1,000,000 K
E) 2,000,000 K

A) heliogeology
B) chromography
C) coronagraphy
D) helioseismology
E) magnetic field mapping

A) meridional flow
B) convection currents
C) differential rotation
D) coronal mass ejections
E) helioseimologic activity

A) is flowing downward towards the core
B) stays horizontal on the surface
C) is spiraling westward
D) is spiraling eastward
E) is flowing upward

A) sunspots
B) corona
C) photosphere
D) supergranules
E) chromosphere

A) Zeeman effect
B) Maunder minimum
C) meridional flow
D) dynamo effect
E) reconnection event

A) eye
B) flare
C) umbra
D) spicule
E) penumbra

A) visible light
B) microwave
C) ultraviolet
D) gamma
E) infrared

A) a positron and a neutrino
B) a positron and a deuterium
C) a neutrino and a deuterium
D) a neutrino and an electron
E) a deuterium and an electron

A) one
B) two
C) three
D) four
E) eight

A) strong force
B) weak force
C) gravitational force
D) Newtonian force
E) electromagnetic force

A) Most of the neutrinos were absorbed by Earth's atmosphere.
B) The neutrinos combined with other particles as they entered Earth's atmosphere.
C) The neutrinos distributed evenly among three different flavors while traveling to Earth.
D) The number of neutrinos was too great to be held in the tank that Davis designed.
E) The other two-thirds of neutrinos dissipated while traveling to Earth.

A) positrons
B) deuterium
C) gamma rays
D) neutrinos
E) electron motion

A) coronal hole
B) dynamo effect
C) convective zone
D) radiative zone
E) Coulomb barrier

A) 4 ⁴ H => ⁴ He - energy
B) 2 ¹ H => ¹ He + energy
C) 4 ¹ H => 2 ¹ He - energy
D) 4 ¹ H => ⁴ He + energy
E) ⁴ H => ⁸ He + energy