Calculate the velocity of sound in a medium where change in pressure and volume takes place according to the law `p=alpha/V^(2)` where `alpha` is a constant. Treat the medium as an ideal gas and assume `rho` as its normal density.

An ideal gas has adiabatic exponenty. It expands according to the law P = alpha V, where is alpha constant. For this process, the Bulk modulus of the gas is

One mole of a gas is enclosed in a cylinde in a cyclinder and occupies a volume of 1.5 L at a pressure 1.5 atm. It is subjected to strong heating due to which temperature of the gas increase according to the relation T = alpha V^(2) , where alpha is a positive constant and V is volume of the gas. a. Find the work done by air in increasing the volume of gas to 9 L . b. Draw the P - V diagram of the process. c. Determine the heat supplied to the gas (assuming gamma = 1.5) .

An ideal gas expands according to the law P^(2) V = constant . The internal energy of the gas

The pressure of an ideal gas varies according to the law P = P_(0) - AV^(2) , where P_(0) and A are positive constants. Find the highest temperature that can be attained by the gas

The velocity of sound in air (V) pressure (P) and density of air (d) are related as V alpha p^(x) d^(y) . The values of x and y respectively are

An ideal gas whose adiabatic exponent equals gamma is expanded according to the law p = alpha V , where alpha is a constant. The initial volume of the gas is equal to V_0 . As a result of expansion the volume increases eta times. Find : (a) The incident of the internal energy of the gas , (b) the work performed by the gas , ( c) the molar heat capacity of the gas in the process.

Statement-1 : The velocity of sound in a gas is not affected by changes in pressure provided temperature of gas remains constant. Statement-2 : This is because velocity of sound is inversely proportional to square root of density of the gas.

One mole of an ideal gas whose pressure changes with volume as P=alphaV , where alpha is a constant, is expanded so that its volume increase eta times. Find the change in internal energy and heat capacity of the gas.

In an adiabatic change, the pressure p and temperature T of a diatomic gas are related by the relation ppropT^alpha , where alpha equals