Calculate the temperature of 4.0 mol of a gas occupying 5 `dm^3` at 3.32 bar (`R = 0.083 " bar " dm^3 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)) .

Calculate the temperature of 5.0 mol of a gas occupying 5 dm^(3) at 3.32 bar pressure. (R = 0.083 bar dm^(3) K^(-1) mol^(-1) )

Calculate the temperature of 4.0 mol of a gas occupying 5 dm^(3) at 3.32 bar pressure. (R = 0083 bar dm^(3) K^(-1) mol^(-1) )

Calculate the temperature of 2.0 mol of a gas occupying 3 dm^(3) at 3.32 bar pressure. (R = 0083 bar dm^(3) K^(-1) mol^(-1) )

Calculate the temperature of 4.0 mol of a gas occupying 5 dm^(3) at 3.32 bar. Strategy : List the variables with the proper units. Then solve the ideal gas equation for T by substituting the values.

Calculate the total pressure in a mixture of 8 g of oxygen and 4 g hydrogen confined in a vessel of 1 dm^(3) at 27^(@)C . (R = 0.083 "bar" dm^(3) K^(-1) mol^(-1))

Calculate the volume occupied by 8.8 g of CO_(2) at 31.1^(@)C and 1 bar pressure. R= 0.083 bar L K^(-1)mol^(-1).

0.1 mole 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) ) .

10mol of an ideal gas confined to a volume of 10L is released into atmosphere at 300K where the pressure is 1bar. The work done by the gas is (R = 0.083 L "bar" K^(-1)mol^(-1))

Pay load is defined as the difference between the mass of displaced air and the mass of the balloon Calculate the pay-load when a balloon of radius 10m mass 100 kg is filled with helium at 1.66 bar at 27^(@)C (Density of air = 1.2 kg m^(-3) and R = 0.083 bar dm 3 K^(-1) mol^(-1) ) .