0.1 ml of an ideal gas has volume `1 dm^3` in a locked box with friction less piston. The gas is in thermal equilibrium with excess of 0.5 m aqueous ethylene glycol at its freezing point. If piston is released all of a sudden at 1 atm then determine the final volume of gas in `dm^3` `(R = 0.08 atm L mol^(–1) K ^(–1) K_f = 2.0 K molal ^(–1) )`.

A cylinder containing an ideal gas ( 0.1 mol of 1.0dm^3 ) is in thermal equilibrium with a large volume of 0.5 molal aqueous solution of ethylene glycol at it's freezing point. If the stoppers S_1 and S_2 ( as shown in the figure) are suddenly withdrawn, the volume of the gas in litres after equilibrium is achieved will be (Given, K_f (water) = 2.0 K kg mol ^(-1), R = 0.08 dm^(3) atm K^(-1)mol^(-1))

Calculate the temperature of 4.0 mol of a gas occupying d dm^(3) at 3.32 bar. (R=0.083 bar dm^(3) K^(-1)mol^(-1)) .

If two moles of an ideal gas at 500 K occupies a volume of 41 litres, the pressure of the gas is (R = 0.082 L atm K^(-1) mol^(-1))

Z us P graph is plotted for 1 mole of hypothetical gas. Volume of gas at this point A is: [R = 0.08 atm L//"mole"-K]

A gas heated from 273 k to 373k at 1atm pressure if the initial volume of the gas is 10L its final volume would be

Density of ideal gas at 2.46 atm and 300 K is 0.8 g//L Hence g-molar mass of gas is : [R = 0.082 "L-atm/mol-K"]