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"]`

An evacuated glass vessel weighs 50 g when empty, 144.0 g when filled with a liquid of density 0.47 gmLand 50.5 g when filled with an ideal gas at 760 mm Hg at 300 K. The molar mass of the ideal gas is ( Given R = 0.0821 L atm k^(-1) mol^(-1)

An evacuated glass vessel weighs 50g when empty, 148.0 g when filled with a liquid of density 0.98gml^(-1) and 50.5g when filled with an ideal gas at 760mm Hg at 300K . The molar mass of the ideal gas is ( Given R = 0.0821 L atm K^(-1) mol^(-1) )

An evacuated vessel weighs 50 g when empty, 144 g when filled with a liquid of density 0.47 g mL^(-1) and 50.5 g when filled with an ideal gas at 760 mm Hg at 300 K. The molar mass of the ideal gas is (Given R=0.082 L atm K^(-1)mol^(-1) )

Density of ideal gas at 2 atm and 600K is 2g/L. Calculate relative density of this with respect to Ne(g) under similar conditions : (given : R=1/12 atm L/mol.K )

Density of ideal gas at 2 atm and 600K is 2g/L. Calculate relative density of this with respect to Ne(g) under similar conditions : (given : R=1/12 atm L/mol.K )

Density of ideal gas at 2 atm and 600K is 2g/L. Calculate relative density of this with respect to Ne(g) under similar conditions : (given : R=1/12 atm L/mol.K )

Density of ideal gas at 2 atm and 600K is 2g/L. Calculate relative density of this with respect to Ne(g) under similar conditions : (given : R=1/12 atm L/mol.K )

8.2 L of an ideal weight 9.0 g at 300 K and 1 atm. pressure. The molecular mass of gas is

PCl_(5)(g) density (in g/L) of mixture at 24 atm and 300 K , when PCl_(5)(g) undergo 50 % decomposition. [R = 0.08 "atm L mol"^(-1) K^(-1)]