6.3: Free Energy of Ions in Solution

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Returning to our continuum model of the solvation free energy, and apply this to solvating an ion. As discussed earlier, \(\Delta G_{\text{sol}}\) will require forming a small cavity in water and turning on the interactions between the ion and water. We can calculate the energy for solvating an ion in a dielectric medium as the reversible work needed to charge the ion from a charge of 0 to its final value \(q\) within the dielectric medium:

\[w = \int_{0}^{q} \Phi_{\text{ion}} dq\]

As we grow the charge, it will induce a response from the dielectric medium (a polarization) that scales with electrostatic potential: \(\Phi = q / 4\pi \varepsilon r\). We take the ion to occupy a spherical cavity with radius \(a\). Although we can place a point charge at the center of the sphere, it is more easily solved assuming that the charge \(q\) is uniformly distributed over the surface of the sphere. Then the electrostatic potential at the surface of the sphere is \(q/4\pi \varepsilon a\) and the resulting work is

\[w = \dfrac{q^2}{8\pi \varepsilon b}\nonumber\]

In a similar manner, we can calculate the energy it takes to transfer an ion from one medium with \(\varepsilon_1\) to another with \(\varepsilon_2\). We first discharge the ion in medium 1, transfer, and recharge the ion in medium 2. The resulting work, the Born transfer energy, is

\[\Delta w = \dfrac{q^2}{8\pi a} \left (\dfrac{1}{\varepsilon_2} - \dfrac{1}{\varepsilon_1} \right ) \nonumber\]

If you choose to distribute the charge uniformly through the spherical cavity, the prefactor \(q^2 /8\pi a\) becomes \(3q^2 /20\pi a\).

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