To an evacuated vessel with movable piston under external pressure of 1 atm and 0.1mole of He and 1 mole of an unknown compound (vapour pressure 0.68 atm at `0^(@)`C) are introduced. Considering the ideal behaviour, the volume (in litre) of the gases at `0^(@)`C is close to:

To an evacuated vessel with movable piston under external pressure of 1 atm 0.1 mole of He and 1.0 mole of an unknown compound vapour pressure 0.68 atm at 0^(@)C are introduced Considering the ideal gas behaviour the total volume (in litre) of the gases at 0^(@)C is close to .

To an evacuated vessel with movable piston under external pressure of 1 atm 0.1 mole of He and 1.0 mole of an unknown compound vapour pressure 0.68 atm at 0^(@)C are introduced Considering the ideal gas behaviour the total volume (in litre) of the gases at 0^(@)C is close to .

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

One litre of oxygen at a pressure of 1 atm and two litres of nitrogen at a pressure of 0.5 atm are introduced into a vessel of volume 1 litre. If there is no change in temperature, the final pressure of the mixture of gas (in atm) is

Find moles of O-atoms in 5.6 litres of SO_(3) at 0^(@)C ,1 atm ?

An ideal mixture of liquids A and B with 2 moles of A and 2 moles of B has a total vapour pressure of 1 atm at a certain temperature. Another mixture with 1 mole of A and 3 moles of B has a vapour pressure greater than 1 atm. But if 4 moles of C are added to second mixture, the vapour pressure comes down to 1 atm. Vapour pressure of C, P_(C)^(@)=0.8 atm. Calculate the vapour pressure of pure A and B :

A gaseous mixture of 2 moles of A, 3 moles of B, 5 moles of C and 10 moles of D is contained in a vessel. Assuming that gases are ideal and the partial pressure of C is 1.5 atm, total pressure is

Assuming ideal behaviour, calculate the vapour pressure of 1.0 molal solution of a non-volatile molecular solute in water at 50^@C . The vapour pressure of water at 50^@C is 0.122 atm.

How many moles of Helium gas occupy 22.4L at 0C and 1atm pressure

Reducing the pressure from 1.0 to 0.5 atm would change the number of molecules in one mole of ammonia to