Two wires of equal length and cross-section area suspended as shown in figure. Their Young's modulus are `Y_(1)` and `Y_(2)` respectively. The equavalent Young's modulus will be

Two wires of equal length and cross-sectional area are suspended as shown in figure. Their Young's modullare Y_1 and Y_2 respectively. The equivalent Young's modulil will bebr>

Two wires of equal length and cross sectional area suspended as shown in Their Young's modulii are Y_1 = 2xx10^(11) Pa and Y_2 = 0.90 xx 10^(11) Pa respectively. What will be the equivalent Young's modulus of combination?

A horizontal rod suspended from two wires of same length and cross - section. Their Young's modulus are Y_(1) and Y_(2) respectively. The equivalent Young's modulus will be

Two wires have identical lengths and areas of cross-section are suspended by mass M . Their Young's modulus are in the ratio 2:5 .

Young's modules of material of a wire of length ' "L" ' and cross-sectional area "A" is "Y" .If the length of the wire is doubled and cross-sectional area is halved then Young's modules will be :

Three vertical wires, I,II and III are supporting a block of mass M in horizontal positon. The wires are to equal length and cross-sectional area. It is given that Young's modulus of wire II, Y_(2) = Y_(3) (Yong's modulus of wire III ). The wire I and III and attached at extreme ends of the block.

The elastic enery stored in a wire of Young's modulus Y is

A wire havinga length L and cross- sectional area A is suspended at one of its ends from a ceiling . Density and young's modulus of material of the wire are rho and Y , respectively. Its strain energy due to its own weight is (rho^(2)g^(2)AL^(3))/(alphaY) . Find the vqalue of alpha

Two wires of equal dimensions and young's modulus Y_1 and Y_2 are connected end to end. What is the equivalent young's modulus for the combination?