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In a cyclotron, which describes the kinetic energy of a proton? The proton's kinetic energy increases in the circular dee but not in the gap. The proton's kinetic energy is constant. The proton's kinetic energy does not increase, only the direction of the velocity vector changes. The proton's kinetic energy increases continuously during the spiraling. The proton's kinetic energy increases in the gap but not in the circular dee.

In a cyclotron, which describes the kinetic energy of a proton? The proton's kinetic energy increases in the circular dee but not in the gap. The proton's kinetic energy is constant. The proton's kinetic energy does not increase, only the direction of the velocity vector changes. The proton's kinetic energy increases continuously during the spiraling. The proton's kinetic energy increases in the gap but not in the circular dee.

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In a cyclotron, which describes the kinetic energy of a proton? The proton's kinetic energy increases in the circular dee but not in the gap. The proton's kinetic energy is constant. The proton's kinetic energy does not increase, only the direction of the velocity vector changes. The proton's kinetic energy increases continuously during the spiraling. The proton's kinetic energy increases in the gap but not in the circular dee.

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