A material has Poissons ratio 0.5. If a uniform rod of it suffers a longitudinal strain of `2 xx 10^(-3)`, then the percentage change in volume is

A material has Poisson's ratio 0.50 . If a uniform rod of it suffers a longitudinal strain of 2 xx 10^(-3) , then the percentage change in volume is

A material has a Poisson's ratio 0.3. It suffers a uniform longitudinal strain 4.5 xx 10^(-3) , calculate the percentage change in its volume.

A wire has Poisson's ratio 0.3 . If the change in the length of the wire on stretching it is 1% then percentage change in the volume of the wire will be

The Poisson’s ratio for a metal is 0.25. If lateral strain is 0.0125, the longitudinal strain will be

If a force is applicable to an elastic wire of the material of Poisson's ratio 0.2 there is a decrease of the cross-sectional area by 1 % . The percentage increase in its length is :

In an adiabatic expansion of air (assume it a mixture of N_2 and O_2 ), the volume increases by 5% . The percentage change in pressure is:

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)

A uniform wire (Y=2xx10^11 N//m^2) is subjected to a longitudinal tensile stress of 5xx10^(7) N//m^2 . If the overall volume change in the wire is 0.02% the fractional decrease in its radius is 5kxx10^(-6) Find the value of k

The Poisson's ratio of a material is 0.4. If a force is applied to a wire of this material, there is a decrease of cross-sectional area by 2%. The percentage increase in its length is

The Young's modulus of the material of a wire is 2xx10^(10) N m^(-2) If the elongation strain is 1% then the energy stored in the wire per unit volume is J m^(-3) is