2. Two conducting semicircles, MN and MO, centered at points O and O¡ respectively, areplaced on a horizontal plane. The radii of the two semicircles are 4 cm and 2 cm,respectively. The two semicircles are in electrical contact at point M. A uniform magneticfield normal to the horizontal plane exists in the region enclosed by the two semicirclesand the line ON, as shown in Figure 2. The magnitude of the magnetic field is0.015 T. An ultrathin conducting rod has one end electrically connected to thesmaller semicircle MO at point O, and is fixed at point O. The rod has a length equals tothe radius of the larger semicircle, and it rotates clockwise around O at a constant angularvelocitygood electrical contact with the larger semicircle MN. At t = 0, the end of the rod P is atB@ = 50 t rad/s. During the rotation, the other end of the rod, labelled as P, is inpoint M. For 0sts:as the rod rotates, it is also in good electrical contact with the20smaller semicircle MO at some point Q, as shown in Figure 2. Assume that theconducting rod has a uniform resistance per unit length, 1 = 5 Q/m. Neglect the

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