[["Question: A gas cell with an optical path length of 10 cm is placed in one arm of a Michelson interferometer. If the light source for the interferometer is a laser with wavelength 632.2 nm, then 100 fringes are counted as the gas cell is evacuated. What is the index of refraction of the original gas?\nChoices:\nA. 1.00063\nB. 1.00032\nC. 1.00016\nD. 0.99968\nAnswer:"," 1.00063"],["Question: A gas cell with an optical path length of 10 cm is placed in one arm of a Michelson interferometer. If the light source for the interferometer is a laser with wavelength 632.2 nm, then 100 fringes are counted as the gas cell is evacuated. What is the index of refraction of the original gas?\nChoices:\nA. 1.00063\nB. 1.00032\nC. 1.00016\nD. 0.99968\nAnswer:"," 1.00032"],["Question: A gas cell with an optical path length of 10 cm is placed in one arm of a Michelson interferometer. If the light source for the interferometer is a laser with wavelength 632.2 nm, then 100 fringes are counted as the gas cell is evacuated. What is the index of refraction of the original gas?\nChoices:\nA. 1.00063\nB. 1.00032\nC. 1.00016\nD. 0.99968\nAnswer:"," 1.00016"],["Question: A gas cell with an optical path length of 10 cm is placed in one arm of a Michelson interferometer. If the light source for the interferometer is a laser with wavelength 632.2 nm, then 100 fringes are counted as the gas cell is evacuated. What is the index of refraction of the original gas?\nChoices:\nA. 1.00063\nB. 1.00032\nC. 1.00016\nD. 0.99968\nAnswer:"," 0.99968"],["Question: A spring of force constant k is stretched a certain distance. It takes twice as much work to stretch a second spring by half this distance. The force constant of the second spring is\nChoices:\nA. k\nB. 2k\nC. 4k\nD. 8k\nAnswer:"," k"],["Question: A spring of force constant k is stretched a certain distance. It takes twice as much work to stretch a second spring by half this distance. The force constant of the second spring is\nChoices:\nA. k\nB. 2k\nC. 4k\nD. 8k\nAnswer:"," 2k"],["Question: A spring of force constant k is stretched a certain distance. It takes twice as much work to stretch a second spring by half this distance. The force constant of the second spring is\nChoices:\nA. k\nB. 2k\nC. 4k\nD. 8k\nAnswer:"," 4k"],["Question: A spring of force constant k is stretched a certain distance. It takes twice as much work to stretch a second spring by half this distance. The force constant of the second spring is\nChoices:\nA. k\nB. 2k\nC. 4k\nD. 8k\nAnswer:"," 8k"],["Question: A single-electron atom has the electron in the l = 2 state. The number of allowed values of the quantum number m_l is\nChoices:\nA. 5\nB. 4\nC. 3\nD. 2\nAnswer:"," 5"],["Question: A single-electron atom has the electron in the l = 2 state. The number of allowed values of the quantum number m_l is\nChoices:\nA. 5\nB. 4\nC. 3\nD. 2\nAnswer:"," 4"],["Question: A single-electron atom has the electron in the l = 2 state. The number of allowed values of the quantum number m_l is\nChoices:\nA. 5\nB. 4\nC. 3\nD. 2\nAnswer:"," 3"],["Question: A single-electron atom has the electron in the l = 2 state. The number of allowed values of the quantum number m_l is\nChoices:\nA. 5\nB. 4\nC. 3\nD. 2\nAnswer:"," 2"],["Question: If the total energy of a particle of mass m is equal to twice its rest energy, then the magnitude of the particle\u2019s relativistic momentum is\nChoices:\nA. mc/2\nB. mc/(2^(1/2))\nC. mc\nD. (3^(1/2))mc\nAnswer:"," mc/2"],["Question: If the total energy of a particle of mass m is equal to twice its rest energy, then the magnitude of the particle\u2019s relativistic momentum is\nChoices:\nA. mc/2\nB. mc/(2^(1/2))\nC. mc\nD. (3^(1/2))mc\nAnswer:"," mc/(2^(1/2))"],["Question: If the total energy of a particle of mass m is equal to twice its rest energy, then the magnitude of the particle\u2019s relativistic momentum is\nChoices:\nA. mc/2\nB. mc/(2^(1/2))\nC. mc\nD. (3^(1/2))mc\nAnswer:"," mc"],["Question: If the total energy of a particle of mass m is equal to twice its rest energy, then the magnitude of the particle\u2019s relativistic momentum is\nChoices:\nA. mc/2\nB. mc/(2^(1/2))\nC. mc\nD. (3^(1/2))mc\nAnswer:"," (3^(1/2))mc"],["Question: The energy required to remove both electrons from the helium atom in its ground state is 79.0 eV. How much energy is required to ionize helium (i.e., to remove one electron)?\nChoices:\nA. 24.6 eV\nB. 39.5 eV\nC. 51.8 eV\nD. 54.4 eV\nAnswer:"," 24.6 eV"],["Question: The energy required to remove both electrons from the helium atom in its ground state is 79.0 eV. How much energy is required to ionize helium (i.e., to remove one electron)?\nChoices:\nA. 24.6 eV\nB. 39.5 eV\nC. 51.8 eV\nD. 54.4 eV\nAnswer:"," 39.5 eV"],["Question: The energy required to remove both electrons from the helium atom in its ground state is 79.0 eV. How much energy is required to ionize helium (i.e., to remove one electron)?\nChoices:\nA. 24.6 eV\nB. 39.5 eV\nC. 51.8 eV\nD. 54.4 eV\nAnswer:"," 51.8 eV"],["Question: The energy required to remove both electrons from the helium atom in its ground state is 79.0 eV. How much energy is required to ionize helium (i.e., to remove one electron)?\nChoices:\nA. 24.6 eV\nB. 39.5 eV\nC. 51.8 eV\nD. 54.4 eV\nAnswer:"," 54.4 eV"],["Question: A particle decays in 2.0 ms in its rest frame. If the same particle moves at v=0.60c in the lab frame, how far will it travel in the lab before decaying?\nChoices:\nA. 150 m\nB. 288 m\nC. 360 m\nD. 450 m\nAnswer:"," 150 m"],["Question: A particle decays in 2.0 ms in its rest frame. If the same particle moves at v=0.60c in the lab frame, how far will it travel in the lab before decaying?\nChoices:\nA. 150 m\nB. 288 m\nC. 360 m\nD. 450 m\nAnswer:"," 288 m"],["Question: A particle decays in 2.0 ms in its rest frame. If the same particle moves at v=0.60c in the lab frame, how far will it travel in the lab before decaying?\nChoices:\nA. 150 m\nB. 288 m\nC. 360 m\nD. 450 m\nAnswer:"," 360 m"],["Question: A particle decays in 2.0 ms in its rest frame. If the same particle moves at v=0.60c in the lab frame, how far will it travel in the lab before decaying?\nChoices:\nA. 150 m\nB. 288 m\nC. 360 m\nD. 450 m\nAnswer:"," 450 m"],["Question: White light is normally incident on a puddle of water (index of refraction 1.33). A thin (500 nm) layer of oil (index of refraction 1.5) floats on the surface of the puddle. Of the following, the most strongly reflected wavelength is\nChoices:\nA. 500 nm\nB. 550 nm\nC. 600 nm\nD. 650 nm\nAnswer:"," 500 nm"],["Question: White light is normally incident on a puddle of water (index of refraction 1.33). A thin (500 nm) layer of oil (index of refraction 1.5) floats on the surface of the puddle. Of the following, the most strongly reflected wavelength is\nChoices:\nA. 500 nm\nB. 550 nm\nC. 600 nm\nD. 650 nm\nAnswer:"," 550 nm"],["Question: White light is normally incident on a puddle of water (index of refraction 1.33). A thin (500 nm) layer of oil (index of refraction 1.5) floats on the surface of the puddle. Of the following, the most strongly reflected wavelength is\nChoices:\nA. 500 nm\nB. 550 nm\nC. 600 nm\nD. 650 nm\nAnswer:"," 600 nm"],["Question: White light is normally incident on a puddle of water (index of refraction 1.33). A thin (500 nm) layer of oil (index of refraction 1.5) floats on the surface of the puddle. Of the following, the most strongly reflected wavelength is\nChoices:\nA. 500 nm\nB. 550 nm\nC. 600 nm\nD. 650 nm\nAnswer:"," 650 nm"],["Question: A 10 kg box slides horizontally without friction at a speed of 1 m/s. At one point, a constant force is applied to the box in the direction of its motion. The box travels 5 m with the constant force applied. The force is then removed, leaving the box with a speed of 2 m/s. Which of the following gives the magnitude of the applied force?\nChoices:\nA. 1 N\nB. 2 N\nC. 3 N\nD. 4 N\nAnswer:"," 1 N"],["Question: A 10 kg box slides horizontally without friction at a speed of 1 m/s. At one point, a constant force is applied to the box in the direction of its motion. The box travels 5 m with the constant force applied. The force is then removed, leaving the box with a speed of 2 m/s. Which of the following gives the magnitude of the applied force?\nChoices:\nA. 1 N\nB. 2 N\nC. 3 N\nD. 4 N\nAnswer:"," 2 N"],["Question: A 10 kg box slides horizontally without friction at a speed of 1 m/s. At one point, a constant force is applied to the box in the direction of its motion. The box travels 5 m with the constant force applied. The force is then removed, leaving the box with a speed of 2 m/s. Which of the following gives the magnitude of the applied force?\nChoices:\nA. 1 N\nB. 2 N\nC. 3 N\nD. 4 N\nAnswer:"," 3 N"],["Question: A 10 kg box slides horizontally without friction at a speed of 1 m/s. At one point, a constant force is applied to the box in the direction of its motion. The box travels 5 m with the constant force applied. The force is then removed, leaving the box with a speed of 2 m/s. Which of the following gives the magnitude of the applied force?\nChoices:\nA. 1 N\nB. 2 N\nC. 3 N\nD. 4 N\nAnswer:"," 4 N"],["Question: Which of the following statements about bosons and/or fermions is true?\nChoices:\nA. Bosons have symmetric wave functions and obey the Pauli exclusion principle.\nB. Bosons have antisymmetric wave functions and do not obey the Pauli exclusion principle.\nC. Fermions have symmetric wave functions and obey the Pauli exclusion principle.\nD. Fermions have antisymmetric wave functions and obey the Pauli exclusion principle.\nAnswer:"," Bosons have symmetric wave functions and obey the Pauli exclusion principle."],["Question: Which of the following statements about bosons and/or fermions is true?\nChoices:\nA. Bosons have symmetric wave functions and obey the Pauli exclusion principle.\nB. Bosons have antisymmetric wave functions and do not obey the Pauli exclusion principle.\nC. Fermions have symmetric wave functions and obey the Pauli exclusion principle.\nD. Fermions have antisymmetric wave functions and obey the Pauli exclusion principle.\nAnswer:"," Bosons have antisymmetric wave functions and do not obey the Pauli exclusion principle."],["Question: Which of the following statements about bosons and/or fermions is true?\nChoices:\nA. Bosons have symmetric wave functions and obey the Pauli exclusion principle.\nB. Bosons have antisymmetric wave functions and do not obey the Pauli exclusion principle.\nC. Fermions have symmetric wave functions and obey the Pauli exclusion principle.\nD. Fermions have antisymmetric wave functions and obey the Pauli exclusion principle.\nAnswer:"," Fermions have symmetric wave functions and obey the Pauli exclusion principle."],["Question: Which of the following statements about bosons and/or fermions is true?\nChoices:\nA. Bosons have symmetric wave functions and obey the Pauli exclusion principle.\nB. Bosons have antisymmetric wave functions and do not obey the Pauli exclusion principle.\nC. Fermions have symmetric wave functions and obey the Pauli exclusion principle.\nD. Fermions have antisymmetric wave functions and obey the Pauli exclusion principle.\nAnswer:"," Fermions have antisymmetric wave functions and obey the Pauli exclusion principle."],["Question: The surface of the Sun has a temperature close to 6,000 K and it emits a blackbody (Planck) spectrum that reaches a maximum near 500 nm. For a body with a surface temperature close to 300 K, at what wavelength would the thermal spectrum reach a maximum?\nChoices:\nA. 10:00 PM\nB. 100 Pm\nC. 10 mm\nD. 100 mm\nAnswer:"," 10:00 PM"],["Question: The surface of the Sun has a temperature close to 6,000 K and it emits a blackbody (Planck) spectrum that reaches a maximum near 500 nm. For a body with a surface temperature close to 300 K, at what wavelength would the thermal spectrum reach a maximum?\nChoices:\nA. 10:00 PM\nB. 100 Pm\nC. 10 mm\nD. 100 mm\nAnswer:"," 100 Pm"],["Question: The surface of the Sun has a temperature close to 6,000 K and it emits a blackbody (Planck) spectrum that reaches a maximum near 500 nm. For a body with a surface temperature close to 300 K, at what wavelength would the thermal spectrum reach a maximum?\nChoices:\nA. 10:00 PM\nB. 100 Pm\nC. 10 mm\nD. 100 mm\nAnswer:"," 10 mm"],["Question: The surface of the Sun has a temperature close to 6,000 K and it emits a blackbody (Planck) spectrum that reaches a maximum near 500 nm. For a body with a surface temperature close to 300 K, at what wavelength would the thermal spectrum reach a maximum?\nChoices:\nA. 10:00 PM\nB. 100 Pm\nC. 10 mm\nD. 100 mm\nAnswer:"," 100 mm"]]
