- #1
zenterix
- 758
- 84
- Homework Statement
- The density of liquid water decreases as the temperature increases from 25C to 50C. Will this effect cause ##K_2## to increase or decrease? Why?
- Relevant Equations
- I thought I knew the answer to this question until today.
Apparently not.
From the van't Hoff equation we have
$$\ln{\left ( \frac{K_p(T_1)}{K_p(T_2)} \right )}=\frac{\Delta H^\circ_{rxn}}{R}\left ( \frac{1}{T_2}-\frac{1}{T_1} \right )\tag{1}$$
So for ##T_2>T_1## we have ##K_p(T_1)<K_p(T_2)##.
which is to say that the equilibrium constant increases for the higher temperature and the reaction shifts towards products (ie ions, hydronium and hydroxide).
Does the analysis above even take into account something like the change in density of water?
Today I learned that the water autoprotolysis constant is
$$\mathrm{K_{auto}=\frac{[H_3O^+][OH^-]}{[H_2O]^2}}\tag{2}$$
and
$$\mathrm{K_w=K_{auto}[H_2O]^2=[H_3O^+][OH^-]}\tag{3}$$
Which of these constants is the one that is considered in (1)?
$$\ln{\left ( \frac{K_p(T_1)}{K_p(T_2)} \right )}=\frac{\Delta H^\circ_{rxn}}{R}\left ( \frac{1}{T_2}-\frac{1}{T_1} \right )\tag{1}$$
So for ##T_2>T_1## we have ##K_p(T_1)<K_p(T_2)##.
which is to say that the equilibrium constant increases for the higher temperature and the reaction shifts towards products (ie ions, hydronium and hydroxide).
Does the analysis above even take into account something like the change in density of water?
Today I learned that the water autoprotolysis constant is
$$\mathrm{K_{auto}=\frac{[H_3O^+][OH^-]}{[H_2O]^2}}\tag{2}$$
and
$$\mathrm{K_w=K_{auto}[H_2O]^2=[H_3O^+][OH^-]}\tag{3}$$
Which of these constants is the one that is considered in (1)?
as this classification is artificial - makes some sense when you start learning, but gets more and more blurry once you get into fine prints).