Around the core of a nuclear reactor shielded by a large pool of water, Cerenkov radiation appears as a blue glow (see figure below). Cerenkov radiation occurs when a particle travels faster through a medium than the speed of light in that medium. It is the electromagnetic equivalent of a bow wave or a sonic boom. An electron is traveling through water at a speed 7.2% faster than the speed of light in water. Department of Energy/Photo Researchers, Inc. (a) Determine the electron's total energy. MeV (b) Determine the electron's kinetic energy. Mey
Around the core of a nuclear reactor shielded by a large pool of water, Cerenkov radiation appears as a blue glow (see figure below). Cerenkov radiation occurs when a particle travels faster through a medium than the speed of light in that medium. It is the electromagnetic equivalent of a bow wave or a sonic boom. An electron is traveling through water at a speed 7.2% faster than the speed of light in water. Department of Energy/Photo Researchers, Inc. (a) Determine the electron's total energy. MeV (b) Determine the electron's kinetic energy. Mey
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Transcribed Image Text:Around the core of a nuclear reactor shielded by a large pool of water, Cerenkov radiation appears as a blue glow (see figure below). Cerenkov radiation occurs when a particle travels faster through a
medium than the speed of light in that medium. It is the electromagnetic equivalent of a bow wave or a sonic boom. An electron is traveling through water at a speed 7.2% faster than the speed of
light in water.
U.S. Department of Energy/Photo Researchers, Inc.
(a) Determine the electron's total energy.
MeV
(b) Determine the electron's kinetic energy.
MeV
(c) Determine the electron's momentum.
MeV/c
(d) Find the angle between the shock wave and the electron's direction of motion.
O
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