Calculate the pressure exerted by 5 moles of `CO_2` in one litre vessel at `47^@`C using Vanderwaal's equation. Also report the pressure of gas if it behaves ideally in nature. Given that a=3.592 atm `lit^2 mol^(-2)`. b = 0.0427 lit `mol^(-1)`

Calculate the pressure exerted by 5 mole of CO_2 in one litre vessel at 47^@C using van der Waals equation. Also report the pressure of gas if it behaves ideal in nature. Given that a = 3.592 atm L^2mol^(-1),b=0.0427Lmol^(-1) . Also, if the volume occupied by CO_2 molecules is negligible, then calculate the pressure exerted by one mole of CO_2 gas at 273 K.

Calculate the pressure exerted by 5 mol of CO_2 in one litre vessels at 47^@C If it behaves ideally in nature.

Calculate the pressure exerted by one mole of CO_2 gas at 273 K, if the Vander Waals constant a = 3.592 dm^6 atm mol^(−2) . Assume that the volume occupied by CO_2 molecules is negligible.

Calculate the final pressure when 2 molesof He at N..T.P. is compressed to 10 lit. Given gamma=1.61

2 moles of ammonia occupied a volume of 5 lit at 27^@C . Calculate the pressure if a=4.17atmL^2 mol^(-2), b= 0.0371 L mol^(-1)

The volume of 2 mole CO_2 gas at 27^@C temperature is 0.001 m^3 . Calculate the pressure of this, gas by applying Ideal gas equation Given that, in case of CO_2, a = 0.364 Nm^4 mol^-1 b = 4.27 xx10^-5 m^3 mol^-1

Calculate the total pressure in a 10 litre cylinder which contains 0.4 g He, 1.6 g O_2 and 1.4 g N_2 at 27^@C . Also calculate the partial pressure of Helium gas in the cylinder. Assume ideal behaviour of gas (R=0.082 litre-atm K^(-1)mol^(-1)

Calculate the osmotic pressure of a 10%. Solution of glucose at 18^@C . R = 0.082 lit atm K^-1 mol^-1 .

Calculate the work done when 1 mol of water vaporises at 100^(@)C and 1 atm pressure. Assume water vapour behaves like an ideal gas.

A gas mixture was prepared by taking equal mole of CO and N_(2) . If total pressure of the mixture was 1 atm, the partial pressure of N_(2) in the mixture is-