Force required to increase the length of wire of area of cross section .A. by one percent, if .Y. is young.s modulus, is

The stress required to double the length of a wire of Young.s modulus .E. is ---

Show that stress required to double the length of wire (or) to produce 100% longitudinal strain is numerically equal to Young's modulus.

When a wire of length 10 m is subjected to a force of 100 N along its length, the lateral strain produced is 0.01 xx 10^3 m . The Poisson's ratio was found to be 0.4. If the area of cross-section of wire is 0.025 m^2, its Young's modulus is

As stone of mass .m. is projected from a rubber catpult of of length . l . and cross-sectional area A stretched by an amount .e.. If Y be the young.s modulus of rubber then find the velocity of projection of stone?

The Young's modulus of steel is twice that of brass. Two wires of the same length and of the same area of cross section, one of steel and another of brass are suspended from the same roof. If we want the lower ends of the wires to be at the same level, then the weights added to the steel and brass wires must be in the ratio of