Assertion Upper wire shown in figure is fixed. At a certain distance x,lower wire can remain in equilibrium.

Reason The above equilibrium of lower wire is stable equilibrium.

Assertion : Current in wire-1 is in the direction as shown in figure. The bottom wire is fixed. To keep the upper wire stationary, current in it should be in opposite direction. Reason : Under the above condition, equilibrium of upper wire is stable.

Two small beads having positive charges 3q and q are fixed at the opposite ends of a horizontal, insulating rod, extending from the origin to the point x=d as shown in fig. A third small charged bead is free to slide on the rod. At what position is the third bead in equilibrium? Can it be in stable equilibrium ?

The force per unit length between two parallel current carrying wires = (mu_(0)i_(1)i_(2))/(2pir) . The force is attractive when the current is in same direction and repulsive, when the they are in opposite directions. The force between the wires of two parallel wires is shown. We can determine the equilibrium position. Then we displace upper wire by a small distance, keeping lower wire fixed. If the wire returns to or tries to return to its equilibrium position, its equilibrium is stable. We can thus show that upper wire can execute linear simple harmonic motion or not. The length of wire AB is large as compared to separation between the wires. If wire CD is in equilibrium position then which of the following may represent the directions of current in the wires

The force per unit length between two parallel current carrying wires = (mu_(0)i_(1)i_(2))/(2pir) . The force is attractive when the current is in same direction and repulsive, when the they are in opposite directions. The force between the wires of two parallel wires is shown. We can determine the equilibrium position. Then we displace upper wire by a small distance, keeping lower wire fixed. If the wire returns to or tries to return to its equilibrium position, its equilibrium is stable. We can thus show that upper wire can execute linear simple harmonic motion or not. The length of wire AB is large as compared to separation between the wires. If lamda is mass per unit length of wire CD, then the equilibrium separation h is given by

The force per unit length between two parallel current carrying wires = (mu_(0)i_(1)i_(2))/(2pir) . The force is attractive when the current is in same direction and repulsive, when the they are in opposite directions. The force between the wires of two parallel wires is shown. We can determine the equilibrium position. Then we displace upper wire by a small distance, keeping lower wire fixed. If the wire returns to or tries to return to its equilibrium position, its equilibrium is stable. We can thus show that upper wire can execute linear simple harmonic motion or not. The length of wire AB is large as compared to separation between the wires. If wire CD is displaced upward to increase the separation by dh, the magnitude of net force per unit length acting on the wire CD becomes

Assertion :Mean positon of SHM is the stable equlibrium position. Reason: In stable equilibrium , position potential energy is minimum.

Assertion (A) : The equilibrium constant is fixed and characteristic for any given chemical reaction at a specified temperature. Reason (R) : The composition of the final equilibrium mixture at a particular temperature depends upon the starting amount of reactants.

Assertion : Two resistance wires shown in figure are of same material. They have equal length. More heat is generated in wire A. Reason : In series H prop R and resistance of wire A is more.

Asseration : A wooden block is floating in a liquid as shown in figure, in vertical direction equilibrium of block stable. . Reason : When depressed in downward direction is starts oscillating.

Consider an inclined plane whose upper half is rough while lower half is smooth. Friction coefficient of the rough surface is µ = 0.8. A heavy rope of mass M is placed on the inclined plane such that it remains in equilibrium. What minimum fraction of rope is required on rough surface for equilibrium?