Webreview - Ch 27 Quantum Physics Practice Test

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Please do write on practice test. ID A Webreview - Ch 27 Quantu Physics Practice Test Multiple Choice Identify the choice that best copletes the stateent or answers the question. 1. Planck's quantu theory is copatible with the experiental data related to which of the following? a. blackbody radiation b. the photoelectric effect c. line spectra eitted by hydrogen gas d. all of the above 2. As the teperature of a radiation eitting blackbody becoes higher, what happens to the peak wavelength of the radiation? a. increases b. decreases c. reains constant d. is directly proportional to teperature e. behaves differently for different teperatures 3. A quantu of radiation has an energy of 2.0 kev. What is its frequency? (h = 6.63 10 34 s and 1 ev = 1.60 10 19 ) a. 3.2 10 17 Hz b. 4.8 10 17 Hz c. 6.3 10 17 Hz d. 7.3 10 17 Hz e. 8.5 10 17 Hz 4. If a quantu of radiation has an energy of 2.0 kev, what is its wavelength? (h = 6.63 10 34 s, 1 ev = 1.60 10 19, c = 3.00 10 8 /s, and 1 n = 10 9 a. 0.32 n b. 0.41 n c. 0.62 n d. 1.02 n e. 1.24 n 5. Classical theories predict that ost of the energy fro a black body should be radiated: a. as theral radiation in the infrared region. b. at the wavelength given by Wien's displaceent law. c. as ultraviolet light. d. as gaa rays. e. a black body should not radiate. 6. The ultraviolet catastrophe predicts that: a. all objects should radiate extree aounts of ultraviolet light. b. as an object gets hotter its light will change fro dull red to blue white. c. a black body can absorb an infinite aount of radiation if the radiation is in the ultraviolet region. d. the radiated energy approaches zero as the wavelength approaches zero. e. a black body will be radiating energy in the ultraviolet region until its teperature approaches to the absolute zero. 1

7. Blue light will not eject electrons fro a certain etal; however, which one of the following ay possibly eject electrons fro that etal? a. infrared b. ultraviolet c. red d. green e. yellow 8. Light of wavelength 6.5 10 7 has an energy of: (h = 6.63 10 34 s, c = 3.00 10 8 /s) a. 3.1 10 19 b. 3.3 10 19 c. 1.5 10 19 d. 1.7 10 19 e. 1.9 10 19 9. If a onochroatic light bea with quantu energy value of 3.0 ev incident upon a photocell where the work function of the target etal is 1.60 ev, what is the axiu kinetic energy of ejected electrons? a. 4.6 ev b. 4.8 ev c. 1.4 ev d. 2.4 ev e. 3.8 ev 10. Which of the following devices represent(s) a practical application of the photoelectric effect? a. hologra b. photocell c. both of the above choices d. none of the above choices 11. According to Einstein, what is true of the stopping potential for a photoelectric current as the wavelength of incident light becoes shorter? a. increases b. decreases c. reains constant d. stopping potential is directly proportional to wavelength e. stopping potential is directly proportional to intensity 12. According to Einstein, as the wavelength of the incident onochroatic light bea becoes shorter, the work function of a target aterial in a phototube: a. increases. b. decreases. c. reains constant. d. is directly proportional to wavelength. e. is inversely proportional to intensity. 2

13. What is the frequency of onochroatic light where the photon energy is 5.5 10 19? (h = 6.63 10 34 s) a. 2.2 10 14 Hz b. 4.4 10 14 Hz c. 8.3 10 14 Hz d. 9.8 10 14 Hz e. 1.4 10 15 Hz 14. What is the wavelength of a onochroatic light bea, where the photon energy is 5.00 10 19? (h = 6.63 10 34 s, c = 3.00 10 8 /s, and 1 n = 10 9 a. 354 n b. 398 n c. 414 n d. 787 n e. 875 n 15. A onochroatic light bea is incident on a bariu target, which has a work function of 2.50 ev. If a stopping potential of 1.0 V is required, what is the light bea photon energy? a. 1.0 ev b. 1.5 ev c. 2.5 ev d. 3.5 ev e. 4.8 ev 16. A light bea is shining on a etal target that has a work function of 2.20 ev. If a stopping potential of 1.30 V is required, what is the wavelength of the incoing onochroatic light? (h = 6.63 10 34 s, c = 3.00 10 8 /s, 1 ev = 1.60 10 19 and 1 n = 10 9 a. 355 n b. 497 n c. 744 n d. 1 421 n e. 1 812 n 17. Light of wavelength 450 n is incident on a target etal that has a work function of 1.80 ev. What stopping potential is required for this cobination in a phototube? (h = 6.63 10 34 s, c = 3.00 10 8 /s, 1 ev = 1.60 10 19 and 1 n = 10 9 a. 0.57 V b. 0.96 V c. 2.76 V d. 4.56 V e. 5.83 V 18. If bariu has a work function of 2.60 ev, what is its cutoff wavelength when used as a phototube target? (h = 6.63 10 34 s, c = 3.00 10 8 /s, 1 ev = 1.60 10 19 and 1 n = 10 9 a. 398 n b. 478 n c. 497 n d. 596 n e. 671 n 3

19. What is the energy of a photon whose frequency is 6.0 10 20 Hz? (h = 6.63 10 34 s and 1 ev = 1.60 10 19 ) a. 1.6 MeV b. 2.5 MeV c. 3.3 MeV d. 4.8 MeV e. 5.9 MeV 20. An ultraviolet light bea having a wavelength of 130 n is incident on a olybdenu surface with work function of 4.2 ev. What is the stopping potential? (h = 6.63 10 34 s, c = 3.00 10 8 /s, 1 ev = 1.6 10 19 a. 1.3 V b. 3.5 V c. 5.4 V d. 11.9 V e. 13.6 V 21. Blue light (λ = 460 n is incident on a piece of potassiu (φ = 2.20 ev). What is the axiu kinetic energy of the ejected photoelectrons? (h = 6.63 10 34 s, c = 3.00 10 8 /s, 1 ev = 1.60 10 19 a. 1.0 ev b. 0.50 ev c. 0.25 ev d. 4.9 ev e. 6.2 ev 22. Light of wavelength 480 n is incident on a etallic surface with a resultant photoelectric stopping potential of 0.55 V. What is the work function of the etal? (h = 6.63 10 34 s, c = 3.00 10 8 /s, 1 ev = 1.60 10 19 a. 2.04 ev b. 3.19 ev c. 2.59 ev d. 0.55 ev e. 0.27 ev 23. Which of the following stateents best describes the relation between the quantu theory and the photoelectric effect experient? a. Quantu theory explains the photoelectric effect. b. The photoelectric effect contradicts quantu theory. c. Quantu theory has no bearing on the photoelectric effect. d. The photoelectric effect explains quantu theory. e. The photoelectric effect is another nae for quantu theory. 4

24. A sodiu vapor lap has a power output of 300 W. If 590 n is the average wavelength of the source, about how any photons are eitted per second? (h = 6.63 10 34 s, c = 3.00 10 8 /s, and 1 n = 10 9 a. 10 17 b. 10 21 c. 10 25 d. 10 29 e. 10 31 25. Of the following photons, which has the highest energy? a. infrared b. icrowave c. visible d. ultraviolet e. radio 26. According to Einstein, increasing the brightness of a bea of light without changing its color will increase: a. the nuber of photons. b. the energy of each photon. c. the speed of the photons. d. the frequency of the photons. e. the ass of each photon. 27. A photon absorbed by an electron will give up ore energy to the electron if the photon: a. is not spread out over any electrons. b. is oving faster. c. is oving slower. d. has a higher frequency. e. An electron cannot absorb a photon. 28. Which change will not change the kinetic energy of the ost energetic electrons eitted in the photoelectric effect? a. changing the brightness of the light b. changing the frequency of the light c. changing the etal the light is hitting d. all of the above will change the electron's kinetic energy e. all of the above will not change the electron's kinetic energy 29. A heliu-neon laser eits red light having a wavelength of 632.8 n and a power of 0.50 W. How any photons are eitted each second? (h = 6.63 10 34 s, c = 3.00 10 8 /s and 1 n = 10 9 a. 1.6 10 15 b. 3.3 10 16 c. 4.8 10 17 d. 2.6 10 18 e. 6.3 10 18 5

30. How uch energy (in ev) does a photon of red light (λ = 700 n have? (h = 6.63 10 34 s, c = 3.00 10 8 /s, 1 ev = 1.60 10 19 a. 3.11 ev b. 2.26 ev c. 1.78 ev d. 1.24 ev e. 1.04 ev 31. What is the axiu velocity of a photoelectron eitted fro a surface with work function 5.00 ev when illuinated by 200 n ultraviolet light? ( electron = 9.11 10 31 kg, h = 6.63 10 34 s, 1 ev = 1.60 10 19 a. 800 000 /s b. 653 000 /s c. 431 000 /s d. 212 000 /s e. 184 000 /s 32. Of the following energies for photons, which is the least energy that could result in photoelectron production if the work function is 3.00 ev? a. 1.50 ev b. 2.90 ev c. 3.50 ev d. 6.01 ev e. 8.14 ev 33. Who was the first to successfully explain the photoelectric effect? a. Planck b. Young c. Bohr d. Einstein e. Heisenberg 34. Sources of red, blue, and yellow light each eit light with a power of 50 W. Which source eits ore photons per second? a. the red source b. the blue source c. the yellow source d. They all eit the sae nuber per second. e. Both red and blue sources eit the sae nuber, and the yellow one eits less. 35. What is the iniu x-ray wavelength produced when electrons are accelerated through a potential of 50 000 V? (h = 6.63 10 34 s, c = 3.00 10 8 /s, and 1 ev = 1.60 10 19 ) a. 12.4 10 12 b. 16.5 10 12 c. 19.8 10 12 d. 24.9 10 12 e. 58.0 10 12 6

39. What is the highest frequency of the photons produced by a 90-kV x-ray achine? (h = 6.63 10 34 36. If the iniu x-ray wavelength produced is 13.5 10 12, through what potential are the electrons accelerated in order to generate this radiation? (h = 6.63 10 34 s, c = 3.00 10 8 /s, and 1 ev = 1.60 10 19 ) a. 33 300 V b. 46 200 V c. 75 000 V d. 92 100 V e. 122 100 V 37. X-ray production occurs in which process? a. photons hitting a etal, eitting electrons b. electrons hitting a etal, eitting photons c. photons hitting a etal, eitting x-rays d. electrons hitting a etal and scattering elastically e. X-rays hitting electrons, eitting secondary x-rays 38. Changing the accelerating voltage of an x-ray achine without changing the target aterial ust change: a. the work function of the aterial. b. the wavelength of all the x-rays produced. c. the wavelength of the iniu wavelength x-ray that will be produced. d. Both b and c are correct. e. None of the above choices is correct. s) a. 1.2 10 19 Hz b. 1.1 10 19 Hz c. 2.4 10 19 Hz d. 2.2 10 19 Hz e. 3.0 10 19 Hz 40. The spacing between atos in KCl crystal is 3.1 10 10. At what angle fro the surface will a bea of 3.14 10 11 x-rays be constructively scattered? a. 57 b. 2.9 c. 90 d. 10 e. 43 7

Webreview - Ch 27 Quantu Physics Practice Test Answer Section MULTIPLE CHOICE 1. D 2. B 3. B 4. C 5. C 6. A 7. B 8. A 9. C 10. B 11. A 12. C 13. C 14. B 15. D 16. A 17. B 18. B 19. B 20. C 21. B 22. A 23. A 24. B 25. D 26. A 27. D 28. A 29. A 30. C 31. B 32. C 33. D 34. A 35. D 36. D 37. B 38. C 39. D 40. B 1

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