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 sound wave passing through an ideal gas at NTP produces a pressure change of 0.001 dyn e//cm^(2)) during adiabatic compression. The corresponding change in temperature (gamma = 1.5 for the gas and atmospheric pressure is 1.013xx10^(6) dyn e//cm^(2)) is

300 cc of a gas is compressed to 150 cc at the atmospheric pressure of 10^6 dyne/ cm^2 . If the change is sudden, what is final pressure ? [Given gamma=1.4 ]

300 cc of a gas is compressed to 150 cc at the atmospheric pressure of 10^6 dyne/ cm^2 . If the change is sudden, what is final pressure ? [Given gamma=1.4 ]

An ideal gas at temperature T_1 is compressed to 32th of its original volume, then its temperature T_2 will be _____ (gamma=1.4)

The changes in pressure an volume of air, when sound wave passes through air are

A sound wave of pressure amplitude 14 pascal propagates through the air medium. The normal pressure of air is 1.0xx10^(5)N//m^(2) the difference between maximum and minimum pressure in the medium is

200 cm^(3) of a gas is compressed to 100cm^(3) at atmospheric pressure (10^(6) "dyne"//cm^(2)) . Find the resultant pressure if the change is (i) slow (ii) sudden Take gamma= 1.4 .

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.