Assume ideal gas behaviour. For the reaction, N2O5(g)⇌2NO2(g)+0.5O2(g), the initial pressure is 600 mmHg and the pressure at any time is 960 mmHg. The fraction of N2O5(g) decomposed at constant volume and temperature is:
0.407
It is a roundabout way of saying that the number of moles of N2O5(g) at t=0 corresponds to 600 mmHg. Or we can say that the number of moles of N2O5(g) at t= 0 exert a pressure of 600 mmHg.
After the system attains chemical equilibrium, at "any time” the equilibrium pressure is 960 mmHg
Volume and temperature are constant. So we can say that at t = 0 and at t = any time after equilibrium, Pressure is proportional to the number of moles.
So we can either speak in terms of concentrations, or in no of moles or in partial pressures.
N2O5(g)⇋2NO2(g)+12O2(g)t=0600 mmHg0 mmHg0 mmHgat any time600 mmHg−p2pp/2
Pressure at any time = (600mmHg−p)+2p+p2=600mmHg+32p=960mmHg
Solving, p = 244 mmHg.
We need the fraction of N2O5 that dissociates = p(600mmHg) = (244mmHg)(600mmHg)=0.407.