Two wires A and B have the same length and area of cross section. But young's modulus of A is two times the young's modulus of B. Then what is the ratio of force constant of A to that of B?

A wire of length L are area of cross section A. Having young's modulus Y of its material, behaves like a spring of force constant k. the value of k will be

Two wires A and B have equal lengths and are made of the same material. But the diameter of A is twice that of wire B. Then for a given load

Two wires A and B have the same cross section and are made of the same material but the length of wire A is twice that of B. Then for a given load

A metal wire of length L, area of cross section A and Young's modulus Y behaves as a spring of spring constant K which is given by

Awire of length L and cross section A is made of material of Young's modulus Y. It is stretched by an amount x. The work done is

A wire of initial length L and area of cross section A, having young's modulus Y of its material, is stretched to be elongated by an amount x. Work done in stretching the wire is

A wire of initial length L and area of cross section A has Young's modulus Y of its material. The wire is stretched by a stress 5 within its elastic limit. The stored energy density in the wire will be

The stress along the length of a rod (with rectangular cross section) is 1% of the Young's modulus of its material. What is the approximate percentage of change of its volume ? (Poisson's ratio of the material of the rod is 0.3)

Two wires A and B both are made of same material and have the same length. The radius of cross section of B is twice that of A. Same loads are suspended from both of them. If the strain in A be 4, then that in B will be