Using van der Waals equation, calculate the constant, a when two moles of a gas confined in a four litre flask exerts a pressure of 11.0 atmospheres at a temperature of 300 K. The value of b is 0.05 L `"mol"^(-1)`

Using van der Waals' equation, find the constant 'a' (in atm L^(2)mol^(-2) ) when two moles of a gas confined in 4 L flask exerts a pressure of 11.0 atmospheres at a temperature of 300 K. The value of b is 0.05 L mol^(-1) .(R = 0.082 atm.L/K mol)

What is the work done when 1 mole of a gas expands isothermally from 25 L to 250 L at a constant pressure of 1 atm and a temperature of 300 K ?

What will be the entropy change when two moles of an ideal gas expand reversibly from initial volume of 1 litre to 10 litre at constant temperature of 300 K?

Calculate the work done when 1.0 mole water at 373K vaporizes against an atmospheric pressure of 1.0 atmosphere. Assume ideal gas behaviour.

Calculate the work done when 1 mol of an ideal gas is compressed reversibly from 1 bar to 4 bar at a constant temperature of 300 K

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))

0.5 moles of gas A and x moles of gas B exert a pressure of 200 Pa in a container of volume 10 m^(3) at 1000K. Given R is the gas constant in jk^(-1) ,x is :

0.5 moles of gas A and x moles of gas B exert a pressure of 200 Pa in a container of volume 10 m^(3) at 1000K. Given R is the gas constant in jk^(-1) ,x is :

Find the temperature at which 3 moles of SO_2 will occupy a volume of 10 litre at a pressure of 15 atm. a=6.71 atm litre^2mol^(−2) ;b=0.0564 litre mol^(−1) .

Find the temperature at which 2 moles of SO_2 will occupy a volume of 10 litre at a pressure of 15 atm. a=6.71 atm litre^2mol^(−2) ;b=0.0564 litre mol^(−1) .