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Study Guide: Unit 1, The Universe and its Stars, HS-ESS1A NAME_______________________ Class ______ Directions: Choose the alternative that best completes the statement or answers the question. 1) HS-ESS1-2 Which of the following colors has the longest wavelength? A) violet B) red C) orange D) green E) blue 2) HS-ESS1-2 Which of the following is NOT considered a form of electromagnetic radiation? A) gamma rays B) x-rays C) gravity D) visible light E) radio waves 3) HS-ESS1-2 The type of spectrum produced by a common light bulb is a ________. A) bright-line (emission) spectrum B) dark-line (absorption) spectrum C) continuous spectrum D) all of the above E) none of the above 4) HS-ESS1-2 The spectra of most stars are of this type. A) continuous spectrum B) bright-line (emission) spectrum C) dark-line (absorption) spectrum D) all of the above E) none of the above 5) HS-ESS1-2 As the temperature of a radiating surface is increased ________. A) the total amount of energy emitted increases B) a larger portion of the energy is radiated at longer wavelengths C) a larger portion of the energy is radiated at shorter wavelengths D) both A and B E) both A and C 6) HS-ESS1-1 Once low- and medium-mass stars consume their remaining thermal fuel, gravity causes them to collapse into ________. A) planetary nebulas B) protostars C) interstellar clouds D) white dwarfs E) black holes 7) HS-ESS1-2 To determine whether a celestial body is approaching or receding from Earth, astronomers employ ________. A) telescopic imaging B) the Stefan-Boltzmann law C) high speed radar D) the Doppler principle E) Einstein's equation 8) HS-ESS1-1 The source of a Star’s energy is ________. A) chemical burning B) nuclear fission C) potential energy D) nuclear fusion E) heat of contraction 9) HS-ESS1-3 The generation of all the elements on the periodic table up to number 26, iron happen during this type of reaction. A) chemical B) endothermic C) physical D) supernova E) exothermic 10) HS-ESS1-1 Theoretical work predicts that during a supernova, the star’s interior condenses into a very hot objects called _______. A) planetary nebulas B) black dwarfs C) white dwarfs D) neutron stars E) black holes 11) HS-ESS1-1 A star produces energy by converting ________. A) carbon monoxide to oxygen nuclei B) oxygen nuclei to nitrogen nuclei C) helium nuclei to hydrogen nuclei D) oxygen nuclei to carbon dioxide E) hydrogen nuclei to helium nuclei 12) HS-ESS1-1 The name applied to concentrations of interstellar matter that glow when it is close to very hot stars is ________. A) granules B) prominences C) nebulas D) quasars E) plages 13) HS-ESS1-1 As _____________ shrinks, gravitational energy is converted into energy of motion, or heat energy, and the mass of contracting gases slowly heats up. A) interstellar clouds B) quasars C) solar winds D) milky way galaxies E) plages 14) HS-ESS1-2 One of the most common units used to express stellar distance is the ________. A) light-year B) kilometer C) mile D) meter 15) HS-ESS1-2 The measure of a star's brightness is called its ________. A) intensity B) color C) magnitude D) parallax 16) HS-ESS1-2 The distance to stars can be determined from ________. A) emission nebulae B) fluorescence C) stellar mass D) stellar parallax 17) HS-ESS1-1 A collapsing cloud of gas and dust destined to become a star is _________? A) nebula B) main-sequence stage C) protostar D) globular clusters 18) HS-ESS1-3 Elements produced by a star heavier than iron on the periodic table happen after this kind of reaction. A) exothermic B) hydrogen burning C) endothermic D) Panorama 19) HS-ESS1-2 Which color stars have the highest surface temperature? A) yellow B) orange C) blue D) red 20) HS-ESS1-2 Which color stars have the coolest surface temperature? A) orange B) yellow C) red D) blue 21) HS-ESS1-2 Which main-sequence stars are the most massive? A) blue B) red C) yellow D) orange 22) HS-ESS1-2 Which main-sequence stars are the least massive? A) orange B) yellow C) blue D) red 23) HS-ESS1-1 Possibly the most cataclysmic event to occur in nature is ________. A) hydrogen burning B) electron degeneration C) a nova D) a supernova 24) HS-ESS1-1 The most dense stars known to exist are ________. A) red dwarfs B) white dwarfs C) black holes D) neutron stars 25) HS-ESS1-1 These stars are produced during a supernova event. A) black hole B) red giant C) white dwarf D) main-sequence star 26) HS-ESS1-2 A star in which light cannot escape because of the immense gravitational pull at its surface is called a ________. A) red giant B) white dwarf C) black hole D) main-sequence star 27) HS-ESS1-1 The final stage in the evolution of the most massive stars is a ________. A) white dwarf B) main-sequence star C) black hole D) red giant 28) HS-ESS1-1 The Sun belongs to this class of stars. A) white dwarf B) red giant C) main-sequence star D) black hole 29) HS-ESS1-1 The point in stellar evolution when a star has used up all its fuel and is radiating away its remaining thermal energy as light is the ________ stage. A) red giant B) main-sequence star C) white dwarf D) black hole 30) HS-ESS1-1 Most stars are in this stage of evolution. A) red giant B) black hole C) main-sequence star D) white dwarf 31) HS-ESS1-1 The final stage for a star which is as massive as the Sun is a ________. A) red giant B) black hole C) main-sequence star D) white dwarf 32) HS-ESS1-1 When a main-sequence star has exhausted the fuel in the inner region, it becomes a ________. A) black hole B) main-sequence star C) black dwarf D) red giant 33) HS-ESS1-2 A first magnitude star is ________ times brighter than a 5th magnitude star. A) 40 B) 100 C) 10 D) 5 34) HS-ESS1-2 Hubble's law states that galaxies are receding from us at a speed that is proportional to their ________. A) orientation B) mass C) distance D) volume 35) HS-ESS1-2 The discovery that the universe appears to be expanding led to a widely accepted theory called ________. A) the Doppler effect B) the Big Bang C) Einstein's Law D) Hubble's Law 36) HS-ESS1-2 Based on the observed red shifts in the spectral lines of distant galaxies, astronomers conclude that ________. A) the universe is expanding B) the universe is contracting C) the universe is in a steady state D) Earth is in the center of the universe ESSAY. Write your answer in the space provided or on a separate sheet of paper. Critical Thinking and Discussion. Use complete sentences, correct spelling, and the information presented in Chapter 24 to answer the questions below. 37) How do we calculate or determine the distances to stars? What units do we use and what are the limitations (if any) of the method used for such calculations? 38) Label the Giant and Supergiant stars, the Main Sequence stars, and the White dwarf stars on the H-R diagram below. 39) Briefly explain the sequence of events that are illustrated in Figure 24.11 below. 1) B 2) C 3) C 4) C 5) E 6) D 7) D 8) D 9) E 10) D 11) E 12) C 13) A 14) A 15) C 16) D 17) C 18) C 19) C 20) C 21) A 22) D 23) A 24) C 25) A 26) C 27) C 28) C 29) C 30) C 31) D 32) D 33) A 34) C 35) B 36) A 37) 38) See Figure 24.7 in Earth Science, 12e. 39) 40)