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A conducting rod whose mass and electrical resistance R slides horizontally without friction on conducting strips, as shown in the figure below. Distance between the bars is. A source of about 8 m is connected between the tracks. In the space there prevails a uniform magnetic field B perpendicular to the plane of the figure in an outward direction. Assuming that the rod started its movement from rest, find the a) The direction of movement of the rod. b) EMF induced in a circuit as a function of speed Traffic. c) Rod speed as a function of time. d) The intensity of the current in the rod as a function of time.

A conducting rod whose mass and electrical resistance R slides horizontally without friction on conducting strips, as shown in the figure below. Distance between the bars is. A source of about 8 m is connected between the tracks. In the space there prevails a uniform magnetic field B perpendicular to the plane of the figure in an outward direction. Assuming that the rod started its movement from rest, find the a) The direction of movement of the rod. b) EMF induced in a circuit as a function of speed Traffic. c) Rod speed as a function of time. d) The intensity of the current in the rod as a function of time.

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A conducting rod whose mass and electrical resistance R slides horizontally without friction on conducting strips, as shown in the figure below. Distance between the bars is. A source of about 8 m is connected between the tracks. In the space there prevails a uniform magnetic field B perpendicular to the plane of the figure in an outward direction. Assuming that the rod started its movement from rest, find the a) The direction of movement of the rod. b) EMF induced in a circuit as a function of speed Traffic. c) Rod speed as a function of time. d) The intensity of the current in the rod as a function of time.

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