Foam instability, causes

Recently Joye et at. [74] have reported a numerical simulation of instability causing asymmetric drainage in foam films. The results obtained confirmed the rapid increase in drainage rate. 

Study of processes leading to rupture of foam films can serve to establish the reasons for their stability. The nature of the unstable state of thin liquid films is a theoretical problem of major importance (it has been under discussion for the past half a century), since film instability causes the instability of some disperse systems. On the other hand, the rupture of unstable films can be used as a model in the study of various flotation processes. The unstable state of thin liquid films is a topic of contemporary interest and is often considered along with the processes of spreading of thin liquid films on a solid substrate (wetting films). Thermodynamic and kinetic mechanisms of instability should be clearly distinguished so that the reasons for instability of thin liquid films could be found. Instability of bilayer films requires a special treatment, presented in Section 3.4.4. 

Stability. The static stability of a foam is the ability to resist bubble breakdown resulting from bubble collapse or coalescence. Foam instability can be caused by the drainage of liquid from the foam resulting from increased quality above 0.95 because of pressure reduction, heating, bubble rupture, or coalescence. 

Suspended particles may consist of complex inorganic hydroxides and silicates or, sometimes, organic debris. Particles too small to be easily distinguished can cause difficulties when a drink is carbonated, acting as minute centres of instability resulting in a loss of carbonation, foaming (gushing) at the filler-head and variable fill volumes. 

The theoretical analysis indicated that asymmetric drainage was caused by the hydrodynamic instability being a result of surface tension driven flow. A criterion giving the conditions of the onset of instability that causes asymmetric drainage in foam films was proposed. This analysis showed as well that surface-tension-driven flow was stabilised by surface dilational viscosity, surface diffusivity and especially surface shear viscosity. 

Atherosclerosis is a chronic inflammation of the arterial vessel wall resulting in plaque formation that eventually may cause cardiovascular events, such as myocardial infarction or cerebral vascular accidents. The presence of autoimmune components in atherosclerosis is well established. Autoantibodies to heat-shock proteins and oxidized low-density lipoproteins (oxLDL) are prevalent in the circulation of patients with atherosclerosis, but the role of these autoantibodies is debated. While anti-oxLDL IgG antibodies may facilitate uptake of oxLDL by foam cells in the lesions, natural IgM antibodies directed to oxLDL may even protect from atherosclerosis. Atherosclerotic plaques also contain some T cells that are considered to be autoreactive, although the respective autoantigens have not yet been identified. These T cells are probably not involved in the plaque formation as such, but they may cause plaque instability, rupture, and subsequent clinical events. 

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