The bar shown in the figure is made of a single piece of material. It is fixed at one end and consists of two segments of equal length `(L)/(2)` but different cross-section area A and 2A. What is the change in length of the system under the action of an axial force F. [ consider the shape of joint to remain circular, Y is young's modulus]

The bar shown in the figure is made of a single piece of material. It is fixed at one end. It consists of two segments of equal lengh L//2 each but different cross sectional area A and 2A . Find the ratio of total elongation in the bar to the elongation produced in thicker segment under the action of an axial force F . Consider the shape of the joint to remain circular. (Given : Y is Young's modulus.

A uniform rod of length 2L, area of cross - section A and Young's modulus Y is lying at rest under the action of three forces as shown. Select the correct alternatives.

A smooth uniform, string of natural length l , cross-sectional area A and Young’s modulus Y is pulled along its length by a force F on a horizontal surface. Find the elastic potential energy stored in the string.

A wire of length L and cross-sectional area A is made of a material of Young's modulus Y. IF the wire is stretched by an amount x, the workdone is

A wire of length L,area of cross section A is hanging from a fixed support. The length of the wire changes to L_1 when mass M is suspended from its free end. The expression for Young's modulus is:

A force of one newton doubles the length of a cord having cross-sectional area 1mrh^(2) . The Young's modulus of the material of the cord is

A catapult consists of two parallel rubber strings each of lengths, 10 cm and cross sectional area 10mm^(2) . When stretched by 5 cm , it can throw a stone of mass 10 gm to a vertical height of 25 m . Determine Young's modulus of elasticity of rubber.

A wire of length L and area of cross-section A, is stretched by a load. The elongation produced in the wire is I. If Y is the Young's modulus of the material of the wire, then the force constant of the wire is

To determine the young's modulus of a wire , the formula is Y = (F)/( A) . (L)/ ( Delta l) , where L = l ength , A = area of cross - section of the wire , DeltaL = change in the length of the wire when streched with a force F . Find the conversion factor to change it from CGS t o MKS system.

The adjacent graph shows the extension Deltal of a wire of length 1m, suspended from the f top of a roof at one end and with a loaf w connected to the other end. If the cross-sectional area of the wire is 10^(6) m^(2) calculate the young's modulus of the material of the wire .