This work presents a theoretical study of the forces established between colloidal particles connected by means of a concave liquid bridge, where the solid particles are partially wetted by a certain amount of liquid also possessing a dry portion of their surfaces. In our analysis, we adopt a two-particle model assuming that the solids are spherical and with the same sizes and properties and that the liquid meniscus features an arc-of-circumference contour. The forces considered are the typical capillary ones, namely, wetting and Laplace forces, as well as the van der Waals force, assuming the particles uncharged. We analyze different parameters which govern the liquid bridge: interparticle separation, wetting angle, and liquid volume, which later determine the value of the forces. Due to the dual characteristic of the particles' surfaces, wet and dry, the forces are to be determined numerically in each case. The results indicate that the capillary forces are dominant in most of the situations meanwhile the van der Waals force is noticeable at very short distances between the particle

Gauckler, Ludwig

Megias-Alguacil, David

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ERRATUMErratum to: Capillary and van der Waals forcesbetween uncharged colloidal particles linked by a liquid bridgeDavid Megias-Alguacil & Ludwig J. GaucklerReceived: 11 June 2010 /Accepted: 1 July 2010 /Published online: 2 September 2010# Springer-Verlag 2010Erratum to: Colloid Polym SciDOI 10.1007/s00396-009-2106-0In a recent paper published in Colloid and Polymer Science [1]dealing with the comparison between the capillary forces andthe van der Waals ones established between colloidal particleslinked by concave liquid bridges, unfortunately there, there isa sign error in Eq. 8, which describes the capillary forcebetween a pair of particles. The correct equation should read,as pointed out by Bakken et al. [2]:Fcap ¼ 2p g R sin a sinða þ qÞþ p g R2sin2a 1L 1r ð1Þwhere γ is the surface tension of the liquid of the bridge, R isthe solid particle’s radius, α is the half-filling angle, θ is thewetting angle and ρ and L are the principal radii of the liquidmeniscus [1].This correction does not affect the method of determiningthe liquid meniscus shape neither the limiting inter-particledistances of the concave liquid bridges, although Eq. 1 altersthe published [1] shape of the capillary force vs. inter-particledistance, H. With the correct equation, repulsive capillaryforces will only persist for wetting angles, θ, lower than ≈20°in a rather limited liquid volume range, Vrel<0.023, and justfor the longest possible distances between particles, practicallyimmediately before the bridge’s rupture, as displayed inFig. 1.When comparing the corrected capillary forces with the vander Waals ones, Fig. 2, qualitatively, similar results thanalready published [1] are found, but now the distances atwhich the ratio FvdW/Fcap diverges are displaced to longerinter-particle separations.With the correct equation for the capillary force, theinduced deep minimum on the total force at inter-particlesdistances close to zero is still persisting. Since the van derWaals force becomes very small when the particles separateand H0 (distances at which Fcap=0) are now found at largerdistances than before [1], as displayed in Fig. 1, the effectof FvdW on H0 is rather small. It is only at extremely lowliquid contents (Vrel<10−5) and wetting angles θ≤20° whereFig. 1 Scaled capillary force, Fcap/(γR), as a function of thedimensionless inter-particle distance, H/R, for different liquid contentswhen θ=0°, according to Eq. 1The online version of the original article can be found at http://dx.doi.org/10.1007/s00396-009-2106-0.D. Megias-Alguacil (*) : L. J. GaucklerDepartment of Materials, Non-Metallic Inorganic Materials,ETH-Zürich,8093 Zürich, Switzerlande-mail: david.megias@mat.ethz.chColloid Polym Sci (2010) 288:1501–1502DOI 10.1007/s00396-010-2262-2the impact of the van der Waals force is noticeable, shiftingthe distances at which Ftot=Fcap+FvdW=0 to slightly largervalues, as shown in Fig. 3. The van der Waals force, FvdW,contribution to H0 is at most 20%, value reached in thelimit of vanishing liquid content and θ=20°. For decreasingangles, the impact of FvdW on H0 is practically negligible.References1. Megias-Alguacil D, Gauckler LJ (2010) Capillary and van derWaals forces between uncharged colloidal particles linked by aliquid bridge. Colloid Polym Sci 288:133–1392. Bakken M, McCulfor J, Anklam MR (2010) Letter to the Editor.AIChE J 56:2489–2490Fig. 3 Inter-particles distances, H0, at which Fcap and Ftot are zero, asa function of the relative volume of meniscus liquid, Vrel, for wettingangles θ=20°Fig. 2 Ratio FvdW /Fcap as a function of the dimensionless inter-particles distance, for several relative volume of meniscus liquid, Vrel,being θ=0° and Adry=10Awet1502 Colloid Polym Sci (2010) 288:1501–1502

Erratum to: Capillary and van der Waals forces between uncharged colloidal particles linked by a liquid bridge

Capillary and van der Waals forces between uncharged colloidal particles linked by a liquid bridge

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Capillary and van der Waals forces between uncharged colloidal particles linked by a liquid bridge

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