Question

Given the reaction...`SO_2(g) + NO_2(g) rightleftharpoons SO_3(g) + NO(g)`...for which `K_"eq"=3.75`, what will be the equilibrium concentrations of products and reactants?

Answer 1

`[SO_3(g)]=0.680+0.216=0.896*mol*L^-1`.

`[NO(g)]=0.680+0.216=0.896*mol*L^-1`.

`[SO_2(g)]=0.680-0.216=0.464*mol*L^-1`.

`[NO_2(g)]=0.680-0.216=0.464*mol*L^-1`.

Explanation:

The equilibrium follows the reaction:

`SO_2(g) + NO_2(g) rightleftharpoons SO_3(g) + NO(g)`

And `K_"eq"=3.75=([SO_3(g)][NO(g)])/([SO_2(g)][NO_2(g)])`

And if `x*mol*L^-1` `SO_2` reacts.................

`K_"eq"=3.75=((0.680+x)(0.680+x))/((0.680-x)(0.680-x))`

`K_"eq"=3.75=(x^2+1.360x+0.462)/(x^2-1.360x+0.462)`

And so,

`3.75x^2-5.10x+1.73=x^2+1.360x+0.462`

And thus, `2.75x^2-6.46x+1.268=0`

This has roots at `x=2.13, or x=0.216` (I used the quadratic equation for this solution!)

Clearly, the lower value is the only solution consistent with the starting conditions. And thus at equilibrium:

`[SO_3(g)]=0.680+0.216=0.896*mol*L^-1`.

`[NO(g)]=0.680+0.216=0.896*mol*L^-1`.

`[SO_2(g)]=0.680-0.216=0.464*mol*L^-1`.

`[NO_2(g)]=0.680-0.216=0.464*mol*L^-1`.

Just as a check, I reput these calculated values back into the equilibrium expression:

`(0.896)^2/(0.464)^2~=3.75` as required........

Good question; I am stealing it for my A2 class...........Gee, they will howl; especially as some of them will use `x=2.13`.