Conservation of Energy in Capillary Tube

I had the same question and found the following excellent answer, which I've restated here with a correction:

Capillary action is minimizing the Helmholtz free energy F of the system.

We can actually find a formula for the capillary height that does this once we have accounted for the three components of energy that change under capillary action:

With $gamma_{L}$ and $gamma_{G}$ as the surface tensions at the liquid-solid and gas-solid interfaces respectively (defined by $gamma = frac{delta F}{delta A})$ then:

If the liquid rises by an amount δh, then we have:

1. $gamma_{L}$ 2πr δh increase in the surface energy due to the liquid-solid contact
2. $gamma_{G}$ 2πr δh decrease in the surface energy due to the gas-solid contact
3. $rho g$ $pi r^2$ h δh increase in the gravitational potential energy of the system where ρ is the difference between the liquid and gas densities, because we're also displacing air and changing the potential energy of that little parcel of air as well.

Overall change in energy $delta F = delta h(pi r^2 rho g h + 2pi r(gamma_L - gamma_G))$.

At equilibrium $delta f = 0$, so $r rho g h + (gamma_L - gamma_G) = 0$ and we have

$$h = frac{gamma_G - gamma_L}{rho g r}$$