358667 The North-pole of a long horizontal bar magnet is being brought closer to a vertical conducting plane along the perpendicular direction. The direction of the induced current in the conducting plane will be:

358668 Statement A :
Lenz's law violates the principle of conservation of energy.
Statement B :
Induced emf always supports the change in magnetic flux responsible for its production.

358669 Consider the situation shown in the figure. If the current \(I\) in the long straight conducting wire \(XY\) is increased at a steady rate then the induced e.m.f. in loops \(A\) and \(B\) will be

358670 A magnet \(NS\) is suspended from a spring and while it oscillates, the magnet moves in and out of the coil \(C\). The coil is connected to a galvanometer \(G\). Then as the magnet oscillates:

358667 The North-pole of a long horizontal bar magnet is being brought closer to a vertical conducting plane along the perpendicular direction. The direction of the induced current in the conducting plane will be:

358668 Statement A :
Lenz's law violates the principle of conservation of energy.
Statement B :
Induced emf always supports the change in magnetic flux responsible for its production.

358669 Consider the situation shown in the figure. If the current \(I\) in the long straight conducting wire \(XY\) is increased at a steady rate then the induced e.m.f. in loops \(A\) and \(B\) will be

358670 A magnet \(NS\) is suspended from a spring and while it oscillates, the magnet moves in and out of the coil \(C\). The coil is connected to a galvanometer \(G\). Then as the magnet oscillates:

358667 The North-pole of a long horizontal bar magnet is being brought closer to a vertical conducting plane along the perpendicular direction. The direction of the induced current in the conducting plane will be:

358668 Statement A :
Lenz's law violates the principle of conservation of energy.
Statement B :
Induced emf always supports the change in magnetic flux responsible for its production.

358669 Consider the situation shown in the figure. If the current \(I\) in the long straight conducting wire \(XY\) is increased at a steady rate then the induced e.m.f. in loops \(A\) and \(B\) will be

358670 A magnet \(NS\) is suspended from a spring and while it oscillates, the magnet moves in and out of the coil \(C\). The coil is connected to a galvanometer \(G\). Then as the magnet oscillates:

358667 The North-pole of a long horizontal bar magnet is being brought closer to a vertical conducting plane along the perpendicular direction. The direction of the induced current in the conducting plane will be:

358668 Statement A :
Lenz's law violates the principle of conservation of energy.
Statement B :
Induced emf always supports the change in magnetic flux responsible for its production.

358669 Consider the situation shown in the figure. If the current \(I\) in the long straight conducting wire \(XY\) is increased at a steady rate then the induced e.m.f. in loops \(A\) and \(B\) will be

358670 A magnet \(NS\) is suspended from a spring and while it oscillates, the magnet moves in and out of the coil \(C\). The coil is connected to a galvanometer \(G\). Then as the magnet oscillates: