Deck 9: Probing the Dynamic Sun

A) an uncharged nuclear particle with mass intermediate between those of the electron and the proton,like a low-mass neutron,capable of penetrating large thicknesses of matter.
B) another name for an electron that carries a positive charge instead of a negative charge.
C) a heavy,uncharged nuclear particle,easily detected.
D) an elusive,subatomic particle having little or no mass,and very difficult to detect.

A) Radiation and convection
B) Conduction and radiation
C) Conduction and convection
D) Radiation alone,by photons of energy

A) balance of gas pressure outward and magnetic forces inward.
B) creation of one helium nucleus for the "destruction" of every four hydrogen nuclei.
C) balance of gas pressure inward and heat outward.
D) balance of gravity inward and gas pressure outward.

A) A heavy nucleus splitting apart to form two lighter nuclei
B) The attachment of electrons to nuclei to form atoms
C) Two nuclei combining to form a new,heavier nucleus
D) The stripping off of electrons to form ions

A) 500,000 years
B) 50 billion years
C) 5 billion years
D) 5 million years

A) The nucleus of a helium atom
B) A positive electron
C) The nucleus of a hydrogen atom
D) A chargeless,massless particle

A) It is spread uniformly through the Sun.
B) In the inner core
C) In the photosphere
D) In the convective zone

A) 20%
B) 0.7%
C) 100%
D) 4%

A) The lost mass is transferred into energy.
B) The mass is lost through friction.
C) The "lost" mass can be accounted for by the masses of the particles emitted as radioactive decay during the interaction.
D) The mass disappears without a trace.

A) It is about 1/2 of the way through its life.
B) It is only 1/10 of the way through its life.
C) It is about 3/4 of the way through its life.
D) It is about 1/4 of the way through its life.

A) just a few seconds because this energy travels at the speed of light.
B) about 10 million years.
C) about 1 year.
D) 170,000 years.

A) convection zone.
B) conduction zone.
C) photosphere.
D) corona.

A) thermonuclear fusion (combining)of hydrogen atoms.
B) thermonuclear fission (splitting)of heavy elements into hydrogen.
C) chemical burning of hydrogen gas with oxygen.
D) gravitational contraction.

A) Fusion of helium into carbon
B) Fission of uranium to form lead
C) Fission of oxygen to form carbon
D) Fusion of hydrogen into helium

A) By photons (radiative transport of energy)
B) By neutrinos streaming outward through the Sun's material (particle transport of energy)
C) By collisions of faster-moving particles with slower-moving particles (conductive transport of energy)
D) By hotter gas rising and cooler gas falling (convective transport of energy)

A) They collide with electrons,producing energy.
B) They collide and stick together to form helium.
C) They combine with neutrons to form protons.
D) They escape from the Sun into space.

A) the rotation of the star.
B) the star's solid core.
C) gas pressure pushing outward.
D) turbulence and upwelling in the atmosphere of the star.

A) radiative zone,convection zone,corona,chromosphere,photosphere.
B) radiative zone,convection zone,chromosphere,photosphere,corona.
C) corona,chromosphere,convection zone,photosphere,radiative zone.
D) radiative zone,convection zone,photosphere,chromosphere,corona.

A) Hydrogen to helium
B) Uranium to lead
C) Helium to hydrogen
D) Splitting of the very abundant iron to lighter elements in a chain reaction,eventually leading to hydrogen

A) The Kepler satellite transit search
B) Neutrino astronomy
C) Observations of surface oscillations on the Sun
D) Magnetic field and sunspot studies

A) The Sun's outer atmosphere
B) The region above the Sun's north and south poles
C) The large region beyond (outside of)the Sun's atmosphere,where the solar wind interacts with the interplanetary magnetic field
D) The Sun's inner atmosphere,just above the photosphere

A) The storm of waves and vortices on the Sun's surface generated by a solar flare
B) The constant flux of photons from the Sun's visible surface
C) The circulation of gases between the equator and the poles of the Sun
D) The Sun's outer atmosphere streaming out into space

A) during lunar eclipses,when the sky is darker.
B) at solar maximum periods,over a period of a few years.
C) during solar eclipses.
D) in spring and fall seasons,because of the tilt of the spin axis of the Sun.

A) about the same as that of the photosphere,5800 K.
B) about twice as hot as the photosphere,12,000 K.
C) very cool because it is farthest from the heat source.
D) very hot-about 106 K.

A) the core of the Sun,where nuclear energy is generated
B) the region of convecting gases below the visible surface of the Sun
C) the middle layer of the Sun's atmosphere
D) the visible "surface" of the Sun

A) It uses up valuable time.
B) Looking directly at the Sun causes blindness.
C) It can lead to baldness.
D) It is bad for the complexion.

A) The core
B) The photosphere
C) The chromosphere
D) The corona

A) The chromosphere
B) The convective zone
C) The photosphere
D) The corona

A) about 10,000 K.
B) 4400 K.
C) 5800 K.
D) close to 1 million K.

A) It is the visible surface of the Sun.
B) It is the layer above the visible surface of the Sun.
C) It is the outermost part of the Sun's atmosphere.
D) It is the layer below the visible surface of the Sun.

A) The corona
B) The chromosphere
C) The radiative zone
D) The convective zone

A) Granules
B) Spicules
C) Sunspots
D) Filaments

A) The core
B) The photosphere
C) The chromosphere
D) The corona

A) The regular impact of meteoroids and comets on the solar surface
B) Differential rotation of the surface layers
C) Thermonuclear fusion in its interior
D) Convective motion under the solar surface

A) Photosphere,chromosphere,corona
B) Chromosphere,photosphere,corona
C) Corona,chromosphere,photosphere
D) Photosphere,corona,chromosphere

A) Corona
B) Chromosphere
C) Prominence
D) Photosphere

A) Sunspots
B) All over the surface,with no preferred location
C) Granulation cells
D) Coronal holes

A) the solar wind.
B) powerful loops of magnetic field linked to active regions.
C) influence on human behavior (e.g. ,astrology).
D) dust released from the Sun.

A) are split by the Zeeman effect due to the strong magnetic fields in the granule.
B) are always redshifted because granules are caused by gas descending into the Sun.
C) are redshifted near the center of the granule and blueshifted near the edge of the granule.
D) are blueshifted near the center of the granule and redshifted near the edge of the granule.

A) A spicule
B) A granule
C) A flare
D) A sunspot

A) Ptolemy
B) Halley
C) Galileo
D) Copernicus

A) A sunspot
B) The solar wind
C) A granule
D) A spicule

A) cooler regions of the Sun's high corona.
B) the shadows of cool,dark curtains of matter,hanging above the solar surface.
C) cooler,darker regions on the Sun's surface.
D) hotter,deeper regions in the Sun's atmosphere.

A) Observation of ionized atoms in the region of the sunspots
B) The Zeeman effect,the splitting of spectral absorption lines
C) The measurement of relative strengths of spectral absorption lines from various atoms
D) Doppler shift of light from sunspots

A) The core
B) The photosphere
C) The chromosphere
D) The corona

A) About 4 rotations per month
B) About 2 rotations per year
C) About 1 rotation per day
D) About 1 rotation per month

A) It would be at a shorter wavelength.
B) It would be at a longer wavelength.
C) It could be at a shorter or longer wavelength,depending on the position of the spot.
D) It would be the same because the light still originates from the hydrogen gas of the Sun.

A) fastest at the equator,slowest at mid-latitudes,and rises to intermediate speeds near the poles.
B) fastest at mid-latitudes,slower at the equator,and slowest near the poles.
C) fastest at the equator,slower at mid-latitudes,and slowest near the poles.
D) slowest at the equator,faster at mid-latitudes,and fastest near the poles.

A) watching bright regions of hydrogen gas drift across the sun.
B) noting the periodic (monthly)variation of auroral disturbances or northern lights.
C) watching sunspots move across the solar surface with a telescope.
D) measuring the Doppler wavelength shift of hydrogen spectral lines from east and west limbs of the Sun.

A) When a light source is moving relative to an observer,the wavelengths of its spectral lines are shifted to longer or shorter wavelengths.
B) When the temperature of a light source is increased,the wavelength of maximum emission decreases.
C) When light shines on a metal surface,electrons are ejected from the metal only if the wavelength of the light is shorter than some critical wavelength.
D) When a light source is located in a magnetic field,the spectral lines it emits are split into two or more components.

A) The reversal of the Sun's magnetic field,which occurs approximately every 11 years
B) The cancellation of the magnetic fields of the northern and southern sunspots when they meet at the Sun's equator
C) The rearrangement of magnetic fields in adjacent arches in the solar atmosphere,with the consequent release of great energy
D) The merging of the triplet of spectral lines in the Zeeman effect into a single line when the magnetic field is removed

A) They increase and decrease in number,relatively regularly.
B) They often occur in pairs of opposite magnetic polarity.
C) They are cooler than the surrounding photosphere of the Sun.
D) They occur in regions of lower-than-average magnetic fields.

A) Magnetic fields inhibit the emission of radiation from atoms in the solar surface.
B) Magnetic fields below the photosphere pull gas down,creating holes in the photosphere.
C) Differential rotation on the Sun creates vortices,or eddies,which are cooler and darker than the rest of the solar surface.
D) Magnetic fields breaking through the photosphere inhibit gas motion where the field is strong,lowering the amount of heat transferred to the surface.

A) Splitting of lines,because the atoms are within an intense magnetic field
B) The change in relative intensity of different lines from sources of different temperature
C) Their shift because of the movement of the source
D) Broadening associated with high temperatures

A) An irregular dark area of uniform darkness
B) A dark center surrounded by a less dark area
C) A roughly circular,dark region with a lighter central area
D) Usually round and of uniform darkness

A) the Moon.
B) the Sun.
C) Jupiter.
D) Saturn.

A) About 2 months
B) 7 years
C) 11 years
D) 22 years

A) Spicules
B) Flares
C) Coronal mass ejections
D) Eruptive prominences

A) coronal hole.
B) prominence.
C) flare.
D) spicule.

A) A loop of gas supported by magnetic fields
B) A jet of gas shot out of the center of a sunspot
C) A shock wave created by the eruption of a solar flare
D) Another name for a sunspot