Answer to Question #210536 in Physical Chemistry for Abrar

The reaction is $2\,NO_{2(g)} ⇄ N_2O_{4(g)}$ and since the pressure is directly linked to the concentration of substances we can define the equilibrium stare for both gases

$\begin{matrix} & 2\,NO_{2(g)} & ⇄ & N_2O_{4(g)} \\ start & 2\,atm=2P_o & & 1\,atm=P_o \\ reaction & -2xP_o & & +xP_o \\ equilibrium & 2P_o(1-x) & & P_o(1+x) \end{matrix}$

Then we find that for $NO_{2(g)}$ we have $\Delta P=-2P_ox$ and from there

$x=-\frac{\Delta P}{2P_o}=\frac{-(-1.24\,atm)}{(2)(1.00\,atm)}=0.62$

This defines $P_{NO_{2(g)}(equilibrium)}=2P_o(1-x)=(2*1\,atm)(1-0.62)=0.76\,atm$

and as well $P_{N_2O_{4(g)}(equilibrium)}=P_o(1+x)=(1\,atm)(1+0.62)=1.62\,atm$

With that information, we can calculate $K_c$ and $K_p$ as

$K_p=\large{ \frac{P_{N_2O_4}}{P_{NO_2}^2} }=\large{ \frac{1.62}{(0.76)^2} }=2.805$

$K_c= \frac{[N_2O_4]}{ [{NO_2}]^2 }=\large{ \frac{ \frac{ P_{N_2O_4}}{RT} }{ ( \frac{P_{NO_2}}{RT} )^2} }= \frac{ P_{N_2O_4} }{ ( P_{NO_2} )^2} * \frac{ (RT)^2 }{ RT } = {K_p}{RT}$

Then we use R=0.0821 atmL/molK and T=298.15 K to find:

$\implies K_c = {K_p}{RT}=(2.805)(0.0821)(298.15)=68.66$

In conclusion, (a) the partial pressures of NO₂ and N₂O₄ at equilibrium are 0.76 atm and 1.62 atm, respectively ; (b) the values calculated for K_c and K_p are 68.66 and 2.805 at 25 °C, respectively.

Reference:

• Atkins, P., & De Paula, J. (2011). Physical chemistry for the life sciences. Oxford University Press, USA.