Stability of Thin Films: Foams
Entry by Grant Gonzalez, 9 Nov 2012
Keywords: Thin Films, Disjoining Forces, Foams, Surfactants
Authors: Arnaud Saint-James, Douglas J. Durian, David A. Weitz
This paper examines the structures of foams, a dispersion of gas within a smaller volume of liquid. Thin films form the interfaces between the gas and liquid faces and are stabilized by surfactants.
Bubbles are dispersed such that liquid thin films are surrounded by gas on both sides, forming a gas-liquid-gas interface. Neighboring bubble surfaces in a foam interact through a variety of forces that depend on the composition and thickness of liquid between them, and on the physical chemistry of their liquid–vapor interfaces. As a result, various interactions affect the stability of thin films. Foam stability therefore is primarily determined by the repulsion of bubble-bubble surfaces, allowing for a layer of liquid to be dispersed between two neighboring bubbles as short distances. Otherwise, the interaction terms will combine and form one bubble. As a result, foams can be considered (while determining stability)as vapor–liquid–vapor film structures formed between neighboring bubbles while considering the interface essentially flat.
A static pressure difference can be imposed between gass-liquid-glass interfaces by several means including gravity. Therefore, the equilibrium film thickness depends on the imposed pressure difference and the effective interface potential. A disjoining pressire p arises when the film thickness does not minimize the potential energy as a function of length, there arises a disjoining pressure p. This disjoining pressure drives the system toward mechanical equilibrium. In response to a hydrostatic pressure, the film thickness thus adjusts itself so that the disjoining pressure balances the applied pressure and mechanical equilibrium is restored.
This paper predicts the disjoining pressure versus film thickness using DLVO theory for an aqueous film containing 1 mM of 1:1 electrolyte. The equilibrium thickness of a free film occurs when the effective interface potential is at a local minimum or when the disjoining pressure vanishes with a negative slope. If the same film is not free, but instead rises vertically from solution in the presence of the earth’s gravitational field, its thickness will vary in response to the height dependence of the hydrostatic pressure. Similar considerations are important for establishing the distribution of liquid around several bubbles packed together in a foam, and hence the bubble shapes. The thin-film balance apparatus allows the creation and study of a single thin film, held on a horizontal support, and at any applied pressure. Hence, this method provides measurement of disjoining pressures vs film thickness (8,9).
Although the details of the interaction between neighboring bubble surfaces in a thin flat film may not be accurately described by the simplest DLVO theory, it nevertheless captures the essential physics. There is a large energy barrier, which prevents two films approaching too closely. This energy barrier may arise from electrostatic repulsion, as in the DLVO model, or it may arise from other interactions. However, its role is primarily to prevent two films from approaching sufficiently close that they fall into the deep attractive well. The degree to which the two films are forced together by external forces determines how high up the energy barrier they are forced; this is in turn parameterized by the disjoining pressure. Should the repulsive barrier be overcome, the films fall 6 FOAMS into the attractive minimum, whereupon they coalesce. Thus this repulsive barrier provides the essential stabilization of the foam. Based on the underlying physical chemistry of surfactants at interfaces, important features of foam structure, stability, rheology, and their interrelationships can be considered as ultimately originating in the molecular composition of the base liquid.
Foams depending on the concentration of liquid to vapor form various structures, depending on the "wetness" of the system. In very wet foams, a forth is formed as excess air bubbles rise to the surface of the liquid and pop. In wet foams, spherical bubbles are formed due to sufficiently strong repulsive interactions; as bubbles rise to the surface, they pack together. In dry foams, polyhedral bubbles result from the severe distortion of spherical bubbles resulting from the lack of liquid in the system.
Foams have potential for application in many roles:
- Oil Recovery
Saint-James, A., Durian, D. J., Weitz, D. A. and Updated by Staff 2012. Foams. Kirk-Othmer Encyclopedia of Chemical Technology. 1–24.