Validity of the "Sharp-Kink Approximation" for Water and Other Fluids Page 8114. Our paper 1 contains two typographical errors, and also some serious mistakes in the equations as presented in the Introduction, which we explain below.The resistivity of the water used in our experiments was 18.2 MΩ-cm, not "8 MΩ" as incorrectly indicated. Also, eq 8 of our paper should state D ) 2C/3z min 3 ) 8πC/9Ṽ . The principal consequence of the mistakes in the equations as presented in the Introduction is that we must take V ) V s in eq 6 of our paper. Since in all of our subsequent calculations we approximated V ) V s anyway, this does not affect any of the results and comparisons made in the paper. Nevertheless, the difference in the meaning of the equations is important.In place of eq 2 of our paper, we should have stated that the gas-solid surface tension σ gs should equal the minimum Ω m of the surface contribution to the grand canonical free energy functional Ω[F(z)] so that eq 3 of our paper should have beenTo arrive at eq 6 of our paper, we then substitute eqs 2.6 and 2.11 from ref 9a, 2 obtaining in the special case l ) d w ) z min where ∆F ) F l -F g is the difference between liquid and gas densities, V s is the attractive potential of the substrate, and F l t is the attractive potential of the liquid. In this equation, d w is the minimum distance of approach to the substrate in the sharp-kink approximation, which in our paper we take to coincide with the minimum of the potential z min (a valid approximation as long as the well depth D is sufficiently deep). By setting Ω m ) Ω(l ) d w ) z min ), we are then in effect assuming that there is, at most, a negligibly thick adsorption layer on the substrate next to the droplet.We then simplify this by substituting eq 2.9 from ref 9a2 where, in the last step, the density of the gas relative to the liquid is neglected. Substituting, we obtain Then, if we substitute this into eq 2 above, we obtainAs stated at the outset, this would be the same as eq 6, which is the central equation of our paper, except that the potential V which appears in the equation should only be the bare substrate potential (V ) V s ). By similar steps, the same equation may be obtained using eq 2.4 for Ω(l) in ref 12b if we set the parameter δ ) 2.
3Our derivation of eq 6 in our paper is not completely general, since we assumed that the adsorption layer next to the droplet is of negligible thickness (l -z min ≈ 0). Profs. L. Schimmele and S. Dietrich, however, recently suggested 4 that the case where a non-negligible adsorption layer of thickness l > d w appears on the substrate is also worth considering, since it would be relevant to investigation of second-order wetting transitions. 4 In this case, substituting eqs 2.6, 2.9, and 2.11 from ref 9a, and making no approximations other than the sharp-kink approximation, we would obtain in terms of the equilibrium thickness l (i.e., coverage l -d w )The first of these two corrections gives the increase in the free energy of the adsorbed film due to the fo...
