A uniform steel rod of cross- sectional area `A` and `L` is suspended so that it hangs vertically. The stress at the middle point of the rod is

A steel bar of cross-sectional area A and length l is magnetised to develop an intensity of magnetisation l . The pole strength of the bar is

A uniform heavy rod of weight W, cross sectional area a and length L is hanging from fixed support. Young modulus of the material of the rod is Y. Neglect the lateral contraction. Find the elongation of the rod.

A rod of uniform cross sectional area 5mm^2 weighing 5 kg and length 1 m is suspended vertically from a fixed support the elongation produced in the rod if [Young's modulus of material, Y=2 x 10^11 N/m^2 and g=10 ms^(-2) ]

A uniform rod AB of length L and mass m is suspended freely at A and hangs vertically at rest when a particle of same mass m is fired horizontally with speed v to strike the rod at its mid point. If the particle is brought to rest after the impact. Then the impulsive reaction at A is horizontal direction is

A copper rod of cross sectional area A carries a uniform current I through it. At temperature T if the volume charge density of the rod is rho how long will the charges take to travel a distance d?

A metal rod of length 'L' and cross-sectional area 'A' is heated through 'T'^(@)C What is the force required to prevent the expansion of the rod lengthwise ?

A steel wire of negligible mass, length 2I , cross sectional area 'A' and Young's modulus 'Y' is held between two rigid walls. A small body of mass 'm' is suspended from its middle point 'O' as shown. The vertical descent of the middle point 'O' of the wire is

A stell rod of length 2l corss sectional area A and mass M is set rotating in a horizotnal plane about an axis passing through its cnetre and perpendicular to its length with constant angular velcoty omega. If Y is the Young's modulus for steel, find the extension in the lenght of the rod. (Assume the rod is uniform.)

A liquid of density rho_0 is filled in a wide tank to a height h. A solid rod of length L, cross-section A and density rho is suspended freely in the tank. The lower end of the rod touches the base of the tank and h=L/n (where n gt 1). Then the angle of inclination theta of the rod with the horizontal in equilibrium position is

Two cylindrical rods of same cross-section area and same length are connected in series to an ideal cell as shown.The resistivity of left rod is rho and that if right rod is 2 rho Then the variation of potential and electric field at any point P distant x from left end of combined rod system are given by