Which of the following gases will you consider to be ideal or real ?
(a) 0.25 mol of `CO_(2)` at 1200 K exerting a pressure of 24.63 atm in 1 L flask.
(b) 6 g of gaseous propanol in 100 mL flask exerts a pressure of `2.4956xx10^(6)` pascal at 300 K.
(c ) 1 mol `CO_(2)` at 300 K occupies volume 22.42 L at 1 atm

Using van der Waals equation, calculate the constant a when 2 mol of a gas confined in a 4 L flasks exerts a pressure of 11.0 atm at a temperature of 300 K . The value of b is 0.05 L mol^(-1) .

Using van der Waals equation, calculate the constant a when 2 mol of a gas confined in a 4 L flasks exerts a pressure of 11.0 atm at a temperature of 300 K . The value of b is 0.05 L mol^(-1) .

(i) Prove that osmotic pressure is a colligative property. (ii) Calculate the molar of urea solution if it exerts an osmotic pressure of 2.45 atmosphere at 300K. (R = 0.0821 L atm. mol^(-1) K^(-1) ).

Using van der Waal's equation calculate the constant 'a' when 2 mole of a gas confined in a 4 L flask exerts a pressure of 11.0 atm at a temperature of 300 K. The value of 'b' is 0.05 L mol^(-1) .

Three moles of the ideal gas are expanded isothermally from a volume of 300 cm^(3) to 2.5 L at 300 K against a pressure of 1.9 atm. Calculate the work done in L and and joules .

A 10 L flask at 298 K contains a gaseous mixture of CO and CO_(2) at a total pressure of 2.0 "bar" if 0.20 mole of CO is present, find its partial pressure and also that of CO_(2) .

At room temperature following traction goes to completion 2AB(g)+B_(2)(g)rarr2AB_(2)(s) AB_(2) is solid with negligble vapour pressure below 0^(@)C . At 300 K, the AB in the smaller flask exerts a pressure of 3 atm and in the larger flask B_(2) exerts a pressure of 1 atm at 400 K when they are separated out by a close valve, The gases are mixed by opening the stop cock and after the end of the reaction the flask are cooled to 250 K The final pressure is :