Calculate the critical volume for one mole of hydrogen if the critical temperature is 240 K and its critical pressure is 12.8 atm. R = `8.31 J m o l^(-1) K ^(-1)`.

Calculate the amount of heat that must be supplied to 40 gm of nitrogen to raise its temperature by 45^(@)C at constant pressure if it is at room temperature. R = 8.3 J mol ^(-1) K ^(-1).

Calculate van der Waals constansts a and b if critical temperature and critical pressure are 30^(@)C and 72 atm respectively .

The essential conditions for liquefaction of gases were discovered by Andrews in 1869 as a result of his study of pressure-volume-temperature relationship for CO_(2) . It was found that above a certain temperature, it was impossible to liquefy a gas whatever the pressure was applied. The temperature below which the gas can be liquefied by the application of pressure alone is called critical temperature (Tc). The pressure required to liquefy a gas at this temperature is called the critical pressure (Pc). The volume occupied by one mole of the substance at the critical temperature and pressure is called critical volume. Critical constants are related with van der waals' constant as follows: V_( c) = 3b, P_( c) =a/(27b^(2)), T_( c) =(8a)/(27 Rb) The values of critical volumes of four gases A, B, C and D are 0.025L, 0.312L, 0.245L and 0.432L respectively. The gas with larger molecular diameter will be :

2 moles of each of hydrogen, carbon dioxide and chlorine are mixed in a close vessel of volume 3 litres and temperature 0^(@)C . Calculate the pressure exerted by the mixture. (R=8.31" J "mol^(-1)K^(-1))

2 moles each of hydrogen, carbon dioxide and chlorine are mixed in a close vessel of volume 3 litres and temperature 0^@ C . Calculate the pressure exerted by the mixture. ( R=8.31 J mol^(-1) K^(-1) )

Calculate the temperature at which the rms velocity of oxygen molecules will be 2 km//s-R = 8.31 J m^(-1) K^(-1) .

One half mole each of nitrogen, oxygen and carbon dioxide are mixed in enclosure of volume 5 litres and temperature 27^(@) C . Calculate the pressure exerted by the mixture. Given R = 8.31 J mol^(-1) K^(-1) .

Calculate the specific heat capacities at constant volume and constant pressure for CO (2), Given gamma = 1.30, R =8.33 J mol ^(-1) K ^(-1).

Calculate the moles of an ideal gas at pressure 2 atm and volume 1 L at a temperature of 97.5 K

A vessel of capacity 10 litres contains 0.5 moles of CO_(2) , 1.3 moles ofnitrogen and 0.20 mole of oxygen at 30^(@)C . Assuming the gases to be ideal, find the pressure of the mixture , R = 8.31 J m o l^(-1) K^(-1) .