Consider a lab in which a detector 2 is located a distance of 3.0 m from detector 1 in the positive x-direction. A particle passes through the detector 2 at a time of t = 0 ns and is moving directly toward detector 1 at a constant speed of 0.80 c, where c is the speed of light. The particle emits a photon at a time of t = 5 ns, also traveling directly toward detector 1. All values in this question part are in the rest frame of the lab. Draw a spacetime diagram in this rest frame in units of light-nanosecond (Lns), with the worldline of detector 1 starting at the origin of the coordinate system. Draw the worldlines for the detector 1, particle, and the photon. Write out all your calculations.
Consider a lab in which a detector 2 is located a distance of 3.0 m from detector 1 in the positive x-direction. A particle passes through the detector 2 at a time of t = 0 ns and is moving directly toward detector 1 at a constant speed of 0.80 c, where c is the speed of light. The particle emits a photon at a time of t = 5 ns, also traveling directly toward detector 1. All values in this question part are in the rest frame of the lab. Draw a spacetime diagram in this rest frame in units of light-nanosecond (Lns), with the worldline of detector 1 starting at the origin of the coordinate system. Draw the worldlines for the detector 1, particle, and the photon. Write out all your calculations.
Consider a lab in which a detector 2 is located a distance of 3.0 m from detector 1 in the positive x-direction. A particle passes through the detector 2 at a time of t = 0 ns and is moving directly toward detector 1 at a constant speed of 0.80 c, where c is the speed of light. The particle emits a photon at a time of t = 5 ns, also traveling directly toward detector 1. All values in this question part are in the rest frame of the lab. Draw a spacetime diagram in this rest frame in units of light-nanosecond (Lns), with the worldline of detector 1 starting at the origin of the coordinate system. Draw the worldlines for the detector 1, particle, and the photon. Write out all your calculations.
e) Consider a lab in which a detector 2 is located a distance of 3.0 m from detector 1 in the positive x-direction. A particle passes through the detector 2 at a time of t = 0 ns and is moving directly toward detector 1 at a constant speed of 0.80 c, where c is the speed of light. The particle emits a photon at a time of t = 5 ns, also traveling directly toward detector 1. All values in this question part are in the rest frame of the lab. Draw a spacetime diagram in this rest frame in units of light-nanosecond (Lns), with the worldline of detector 1 starting at the origin of the coordinate system. Draw the worldlines for the detector 1, particle, and the photon. Write out all your calculations.
Definition Definition Rate at which light travels, measured in a vacuum. The speed of light is a universal physical constant used in many areas of physics, most commonly denoted by the letter c . The value of the speed of light c = 299,792,458 m/s, but for most of the calculations, the value of the speed of light is approximated as c = 3 x 10 8 m/s.
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