Question #0f696

1 Answer
Truong-Son N.
Sep 6, 2017

K ~~ 9.226 xx 10^(-5)

This is just a fancy way of making use of the state function property of the Gibbs' free energy, i.e.

  • ...that it does not matter what path you take, as long as you know what the initial and final states are, and...
  • ...the steps in a path add to give the overall DeltaG (at a given temperature and pressure).

We know that:

DeltaG_"tot" = DeltaG_1 + DeltaG_2 + . . .

And so, at 25^@ "C" and "1 atm", the DeltaG^@ for the overall reaction is related to the individual DeltaG^@ values.

DeltaG_1^@ + DeltaG_2^@ = DeltaG_"rxn"^@ = -"8.80 kJ/mol"

And you were given that DeltaG_2^@ = -"31.6 kJ/mol". As a result, for the first reaction we have:

DeltaG_1^@ = DeltaG_"rxn"^@ - DeltaG_2^@

= -"8.80 kJ/mol" - (-"31.6 kJ/mol")

= "22.8 kJ/mol"

Now, DeltaG at NONSTANDARD conditions (not at 25^@ "C" but still at "1 atm") is related to the STANDARD change in Gibbs' free energy DeltaG^@:

DeltaG = DeltaG^@ + RTlnQ

where Q is the reaction quotient (for NOT being at equilibrium).

At chemical equilibrium, DeltaG = 0, and Q = K, so:

ul(DeltaG^@ = -RTlnK)

Knowing DeltaG_1^@, the change in the Gibbs' free energy for the first reaction step, we can then get the equilibrium constant for that first reaction step:

color(blue)(K) = e^(-DeltaG_1^@ // RT)

= e^(-"22.8 kJ/mol" // ("0.008314472 kJ/mol"cdot"K" cdot (22 + "273.15 K"))

= ulcolor(blue)(9.226 xx 10^(-5))

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