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Answer 1 · 2017-06-26T14:56:36

$K_c = 5.81 xx 10^(-3)$

We're asked to find the equilibrium constant $K_c$ for this reaction, given an initial and final equilibrium concentration.

The equilibrium constant expression for this reaction is

$K_c = (["SO"_2]^2["O"_2])/(["SO"_3]^2)$

If $0.840$ moles of $"SO"_3$ is placed in a $4.50$ - $"L"$ container, the initial concentration is

$["SO"_3] = (0.840color(white)(l)"mol")/(4.50color(white)(l)"L") = 0.187M$

We can tabulate now our initial concentrations for each species:

Initial:

The changes in concentration, which we'll call the variable $x$ , can be expected via the coefficients of the equation:

Change:

We know the final equilibrium concentration of $"O"_2$ is

$["O"_2] = (0.130color(white)(l)"mol")/(4.50color(white)(l)"L") = 0.0289M$

Therefore, the variable $x$ must be equal to this value, because the oxygen concentration change is " $+x$ ", and hence $0 + x = 0.0289$

Using this value, we can now find the equilibrium concentrations of all species:

Equilibrium:

And lastly, we can plug in these values to the equilibrium constant expression to calculate $K_c$ :

$K_c = ((0.0578M)^2(0.0289M))/((0.129M)^2) = color(blue)(5.81 xx 10^(-3)$