Chapter 09 Tests

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Question 1 1) core 2) corona 3) photosphere 4) chromosphere 5) convection zone The visible light we see from our Sun comes from which part?

Question 1 The visible light we see from our Sun comes from which part? 1) core 2) corona 3) photosphere 4) chromosphere 5) convection zone The photosphere is a relatively narrow layer below the chromosphere and corona, with an average temperature of about 6000 K.

Question 2 The density of the Sun is most similar to that of 1) a comet. 2) Jupiter. 3) the Earth. 4) interstellar gas. 5) an asteroid.

Question 2 1) a comet. 2) Jupiter. 3) the Earth. 4) interstellar gas. 5) an asteroid. The Sun is a ball of charged gas, without a solid surface. Jupiter has a similar composition, but not enough mass to be a star. The density of the Sun is most similar to that of

Question 3 The Sun is stable as a star because 1) gravity balances forces from pressure. 2) the rate of fusion equals the rate of fission. 3) radiation and convection balance. 4) mass is converted into energy. 5) fusion doesn’t depend on temperature.

Question 3 The Sun is stable as a star because 1) gravity balances forces from pressure. 2) the rate of fusion equals the rate of fission. 3) radiation and convection balance. 4) mass is converted into energy. 5) fusion doesn’t depend on temperature. The principle of Hydrostatic Equilibrium explains how stars maintain their stability.

Question 4 The proton–proton cycle involves what kind of fusion process? 1) carbon (C) into oxygen (O) 2) helium (He) into carbon (C) 3) hydrogen (H) into helium (He) 4) neon (Ne) into silicon (Si) 5) oxygen (O) into iron (Fe)

Question 4 In the P-P cycle, four Hydrogen nuclei (protons) fuse into one Helium nucleus, releasing gamma rays and neutrinos. The proton–proton cycle involves what kind of fusion process? 1) carbon (C) into oxygen (O) 2) helium (He) into carbon (C) 3) hydrogen (H) into helium (He) 4) neon (Ne) into silicon (Si) 5) oxygen (O) into iron (Fe)

Question 5 If a neutrino can escape from the solar core within minutes, then how long does it take a photon to escape? 1) minutes 2) hours 3) months 4) hundreds of years 5) about a million years

Question 5 If a neutrino can escape from the solar core within minutes, then how long does it take a photon to escape? 1) minutes 2) hours 3) months 4) hundreds of years 5) about a million years Gamma ray photons are absorbed and re-emitted continuously in the layers above the core. They gradually shift in spectrum to visible and infrared light at the photosphere.

Question 6 What is probably responsible for the increase in temperature of the corona far from the Sun’s surface? 1) a higher rate of fusion 2) the Sun’s magnetism 3) higher radiation pressures 4) absorption of X-rays 5) convection currents

Question 6 What is probably responsible for the increase in temperature of the corona far from the Sun’s surface? 1) a higher rate of fusion 2) the Sun’s magnetism 3) higher radiation pressures 4) absorption of X-rays 5) convection currents Apparently the Sun’s magnetic field acts like a pump to increase the speeds of particles in the upper corona.

Question 7 The number of sunspots and solar activity in general peaks 1) every 27 days, the apparent rotation period of the Sun’s surface. 2) once a year. 3) every 5 ½ years. 4) every 11 years. 5) approximately every 100 years.

Question 7 1) every 27 days, the apparent rotation period of the Sun’s surface. 2) once a year. 3) every 5 ½ years. 4) every 11 years. 5) approximately every 100 years. The sunspot cycle shows a consistent 11-year pattern of activity dating back more than 300 years. The number of sunspots and solar activity in general peaks

Question 8 The “Solar Neutrino Problem” refers to the fact that astronomers 1) cannot explain how the Sun is stable. 2) detect only one-third the number of neutrinos expected by theory. 3) cannot detect neutrinos easily. 4) are unable to explain how neutrinos oscillate between other types. 5) cannot create controlled fusion reactions on Earth.

Question 8 The “Solar Neutrino Problem” refers to the fact that astronomers 1) cannot explain how the Sun is stable. 2) detect only one-third the number of neutrinos expected by theory. 3) cannot detect neutrinos easily. 4) are unable to explain how neutrinos oscillate between other types. 5) cannot create controlled fusion reactions on Earth. Further experiments have shown that solar neutrinos can change into other types that were not initially detected.

Chapter 09 Tests

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Chapter 09 Tests