For a metal `Y = 1.1xx10^(10) N//m^(2)` and Bulk modulus is `K = 11xx10^(10) N//m^(2)` then Poisson's ratio is (nearly)

For a material Y = 6.6xx10^(10) Nm^(2) and bulk modulus K = 11xx10^(10) N//m^(2) , then its Poisson's ratio is

For silver Young's modulus is 7.5 xx 10^(10) N//m^(2) and Bulk modulus is 11 xx 10^(10) N//m^(2) . Its poisson's ratio will be

For silver, Young's modulus is 7.25 xx 10^(10) N//m^(2) and Bulk modulus is 11 xx 10^(10) N//m^(2) . What is its Poisson's ratio ?

The following values for a clastic material : Young's =7xx10^(10) Nm^(-2) and Bulk modulus =11xx10^(10) Nm^(-2) . The poisson's ratio of the material is -

Assertion : A given mass of a gas is subjected to an external pressure of 0.5xx10^(10) N//m^(2) , the bulk modulus of the gas is 0.5xx10^(10) N//m^(2) . The ratio of the density of the gas before and after applying the external pressure is 1 : 1 Reason : Pressure is inversely proportional to density of gas and bulk modulus is inversely proportional to change in volume

The bulk modulus of water is 2.3xx10^(9)N//m^(2) its compressibility is

The Young's modulus of a material is 2xx10^(11)N//m^(2) and its elastic limit is 1xx10^(8) N//m^(2). For a wire of 1 m length of this material, the maximum elongation achievable is

Young's modulus of a metal is 21xx10^(10)N//m^(2) . Express it in "dyne/cm"^(2) .

A solid sphere of radius 0.2 m is subjected to a uniform pressure of 10^(5)N//m^(2) . If the bulk modulus of the material is 1.6xx10^(11)N//m^(2) , then the decrease in the volume of the sphere is approximately will be

A body of volume 10^(-3)m^(3) is compressed such that its volume decreases by 0.2xx10^(-6)m^(3) . If its bulk modulus is 2xx10^(10)N//m^(2) , then the pressure applied will be