Please use this identifier to cite or link to this item: http://hdl.handle.net/1959.3/190615

Title

Theory of non-equilibrium force measurements involving deformable drops and bubbles

Author(s)

Chan, Derek Y. C.;  Klaseboer, Evert;  Manica, Rogerio

Abstract

Over the past decade, direct force measurements using the Atomic Force Microscope (AFM) have been extended to study non-equilibrium interactions. Perhaps the more scientifically interesting and technically challenging of such studies involved deformable drops and bubbles in relative motion. The scientific interest stems from the rich complexity that arises from the combination of separation dependent surface forces such as Van der Waals, electrical double layer and steric interactions with velocity dependent forces from hydrodynamic interactions. Moreover the effects of these forces also depend on the deformations of the surfaces of the drops and bubbles that alter local conditions on the nanometer scale, with deformations that can extend over micrometers. Because of incompressibility, effects of such deformations are strongly influenced by small changes of the sizes of the drops and bubbles that may be in the millimeter range. Our focus is on interactions between emulsion drops and bubbles at around 100 μm size range. At the typical velocities in dynamic force measurements with the AFM which span the range of Brownian velocities of such emulsions, the ratio of hydrodynamic force to surface tension force, as characterized by the capillary number, is ~10^−^6 or smaller, which poses challenges to modeling using direct numerical simulations. However, the qualitative and quantitative features of the dynamic forces between interacting drops and bubbles are sensitive to the detailed space and time-dependent deformations. It is this dynamic coupling between forces and deformations that requires a detailed quantitative theoretical framework to help interpret experimental measurements. Theories that do not treat forces and deformations in a consistent way simply will not have much predictive power. The technical challenges of undertaking force measurements are substantial. These range from generating drop and bubble of the appropriate size range to controlling the physicochemical environment to finding the optimal and quantifiable way to place and secure the drops and bubbles in the AFM to make reproducible measurements. It is perhaps no surprise that it is only recently that direct measurements of non-equilibrium forces between two drops or two bubbles colliding in a controlled manner have been possible. This review covers the development of a consistent theory to describe non-equilibrium force measurements involving deformable drops and bubbles. Predictions of this model are also tested on dynamic film drainage experiments involving deformable drops and bubbles that use very different techniques to the AFM to demonstrate that it is capable of providing accurate quantitative predictions of both dynamic forces and dynamic deformations. In the low capillary number regime of interest, we observe that the dynamic behavior of all experimental results reviewed here are consistent with the tangentially immobile hydrodynamic boundary condition at liquid-liquid or liquid-gas interfaces. The most likely explanation for this observation is the presence of trace amounts of surface-active species that are responsible for arresting interfacial flow.

Publication type

Journal article

Source

Advances in Colloid and Interface Science: a collection of papers presented at XIVth International Conference on Surface Forces, Moscow and St. Petersburg, Russia, 21-27 June 2010, Vol. 165, no. 2 (Jul 2011), pp. 70-90

Publication year

2011

FOR Code(s)

0306 Physical Chemistry (Incl. Structural);  0904 Chemical Engineering

Keyword(s)

AFM force measurements;  Coalescence;  Deformable drops and bubbles;  Film drainage;  Young-Laplace;  Stokes-Reynolds

Publisher

Elsevier BV

ISSN

0001-8686

Publisher URL

http://dx.doi.org/10.1016/j.cis.2010.12.001

Copyright

Copyright © 2010 Elsevier B.V.

Peer reviewed