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In the figure, a long rectangular conducting loop, of width L = 13 cm, resistance R = 12 Ω, and mass m = 0.082 kg , is hung in a horizontal, uniform magnetic field of magnitude 1.1 T that is directed into the page and that exists only above line aa. The loop is then dropped; during its fall, it accelerates until it reaches a certain terminal speed vt. Ignoring air drag, find the terminal speed. Number Units

In the figure, a long rectangular conducting loop, of width L = 13 cm, resistance R = 12 Ω, and mass m = 0.082 kg , is hung in a horizontal, uniform magnetic field of magnitude 1.1 T that is directed into the page and that exists only above line aa. The loop is then dropped; during its fall, it accelerates until it reaches a certain terminal speed vt. Ignoring air drag, find the terminal speed. Number Units

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In the figure, a long rectangular conducting loop, of width L = 13 c m , resistance R = 12 Ω , and mass m = 0.082 kg , is hung in a horizontal, uniform magnetic field of magnitude 1.1 T that is directed into the page and that exists only above line aa. The loop is then dropped; during its fall, it accelerates until it reaches a certain terminal speed v t . Ignoring air drag, find the terminal speed. Number i Units

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