A sound wave passing through air at `NTP` produces a pressure of `0.001 "dyne"/cm^2` during a compression. The corresponding change in temperature (given `gamma = 1.5` and assume gas to be ideal) is

A mass of diatomic gas (gamma=1.4) at a pressure of 2 atomphere is compressed adiabitically so that its temperature rises from 27^(@)C to 927^(@)C . The pressure of the gas in the final state is

One mole of an ideal gas passes through a process where pressure and volume obey the relation P=P_0 [1-1/2 (V_0/V)^2] Here P_0 and V_0 are constants. Calculate the change in the temperature of the gas if its volume changes from V_0 to 2V_0 .

We have 0.5 g of hydrogen gas in a cubic chamber of size 3 cm kept at NTP. The gas in the chamber is compressed keeping the temperature constant till a final pressure of 100 atm. Is one justified in assuming the ideal gas law in the final state ? (Hydrogen molecules can be consider as spheres of radius 1Å ).

Statement -I : There is no change in enthalpy of an ideal gas during compression at constant temperature. Statement-II: Enthalpy of an ideal gas is a function of temperature and pressure.

500cm^(3) of a sample of an ideal gas is compressed by an average pressure of 0.1 atm of 250 cm^(3) . During this process, 10J of heat flows out to the surroundings. Calculate the change in internal enegry of the system.

500cm^(3) of a sample of an ideal gas is compressed by an average pressure of 0.1 atm of 250 cm^(3) . During this process, 10J of heat flows out to the surroundings. Calculate the change in internal enegry of the system.

300K a gas (gamma = 5//3) is compressed adiabatically so that its pressure becomes 1//8 of the original pressure. The final temperature of the gas is :

In fig. the walls of the container and the piston are weakly conducting. The initial pressure, volume and temperature of the gas are 200KPa, 800 cm^(3) and 100 K resp . Find the pressure and the temperature of the gas it it is (a) slowly compressed (b) suddenly compressed to 200 cm^(3) (gamma = 1.5) .

50g of oxygen at NTP is compressed adiabatically to a pressure of 5 atmosphere. The work done on the gas, if gamma =1.4 and R = 8.31 J mol^(-1)K^(-1) is

Statement-1: The speed of sound in humid air is more than the speed of sound in dry air keeping pressure constant. Statement-2: Speed of sound in air with respect to air remains constant at a given temperature. Statement-3: Transverse waves cannot be polarised.