A wooden cubical block ABCDEFG of mass m and side a is wrapped by a square wire loop of perimeter 4a, carying current I. The whole system is placed at frictionless horizontal surface in a uniform magnetic field `vecB=B_0hatj` as shown in fig. In this situation, normal force between horizontal surface and block passes through a point at a distance x from centre. Choose correct statement (s).

A wooden cubical block ABCDEFG of mass m and side a is wrapped by a square wire loop of perimeter 4a , carrying current I. The whole system is placed at frictionless horizontal surface in a uniform magnetic field vecB=B_(0)hatj as shown in figure. In this situation, normal force between horizontal surface and clock passes through a point at a distance x from centre. Choose correct statement (s).

A circular wire loop of radius R, mass m carrying current I lies on a rough surface (as shown in Fig. 1.86). There is a horizontal magnetic field vec B. How large can the current I be before one edge of the loop will lift off the surface?

Two blocks of equal mass m are connected by an unstretched spring and the system is kept at rest on a frictionless horizontal surface. A constant force F is applied on the first block pulling away from the other as shown in Fig. Then the displacement of the centre of mass in at time t is

Two blocks of masses m_(1) and m_(2) are connected with a light spring of force constant k and the whole system is kept on a frictionless horizontal surface. The masses are applied forces F_(1) and F_(2) as shown in fig. At any time the blocks have same acceleration a_(0) but in opposite direction. Now answer the following : the value of spring force is

Two blocks of masses m_(1) and m_(2) are connected with a light spring of force constant k and the whole system is kept on a frictionless horizontal surface. The masses are applied forces F_(1) and F_(2) as shown in fig. At any time the blocks have same acceleration a_(0) but in opposite direction. Now answer the following : The value of a_(0) is

Two blocks of equal mass m are connected by an unstretched spring and the system is kept at rest on a frictionless horizontal surface. A constant force F is applied on the first block pulling away from the other as shown in Fig. If the extension of the spring is x_(0) at time t , then the displacement of the first block at this instant is

Two blocks of equal mass m are connected by an unstretched spring and the system is kept at rest on a frictionless horizontal surface. A constant force F is applied on the first block pulling away from the other as shown in Fig. If the extension of the spring is x_(0) at time t , then the displacement of the first block at this instant is

Two blocks of masses m_(1) and m_(2) are connected with a light spring of force constant k and the whole system is kept on a frictionless horizontal surface. The masses are applied forces F_(1) and F_(2) as shown in fig. At any time the blocks have same acceleration a_(0) but in opposite direction. Now answer the following : If F_(2) is removed at this moment, then just after the acceleration of m_(2) is

Two masses m_1 and m_2 re connected by a spring of spring constant k and are placed on as frictionless horizontal surface. Initially the spring is stretched through a distance x_0 when the system is released from rest. Find the distance moved by the two masses before they again come to rest.

A uniform square block of side 'a' and mass 'm' is lying on a horizontal surface. A small block of mass m is placed on the top block. Find the distance by which normal reaction is shifted.