The Society of Rheology 87th Annual Meeting

October 11-15, 2015 - Baltimore, Maryland

Paper Number
IR11 

Session
Interfacial Rheology

Title
Influence of interfacial rheology on the volume of liquid entrained in a foam film

Presentation Date and Time
October 12, 2015 (Monday) 4:00

Track / Room
Track 3 / Constellation E

Authors (Click on name to view author profile)

  1. Frostad, John M. (Stanford University, Chemical Engineering)
  2. Tammaro, Daniele (University of Naples Federico II, Dipartimento di Ingegneria Chimica, dei Materiali e della Pr)
  3. Santollani, Luciano (Stanford University, Chemical Engineering)
  4. Bochner de Araujo, Simone (Stanford University)
  5. Fuller, Gerald G. (Stanford University, Department of Chemical Engineering)

Author and Affiliation Lines (in printed abstract book)
John M. Frostad1, Daniele Tammaro2, Luciano Santollani1, Simone Bochner de Araujo1, and Gerald G. Fuller1
1Department of Chemical Engineering, Stanford University, Stanford, CA; 2Dipartimento di Ingegneria Chimica, dei Materiali e della Pr, University of Naples Federico II, Napoli, Italy

Speaker / Presenter 
Frostad, John M.

Text of Abstract
Bubble columns that produce foam are commonly found in waste water treatment and other industrial processes. The head on a glass of beer is another familiar example of foam formed by bubbles rising through a liquid and collecting on the surface. The characteristics of the foam that is formed in these systems such as the foam height, density and lifetime are all dependent on the properties of the surface-active compounds that are present in the liquid. In the present work, a fundamental study of single bubble interactions at a planar air-liquid interface is performed. When a single bubble moves upward and reaches the interface, a thin film of liquid is formed that drains and eventually ruptures. The volume of liquid initially entrained in this film is important in determining the properties of the resulting foam. For example, thicker films will tend to produce “wetter”, more dense foams. A thicker film may also take longer to drain and therefore result in taller foam heights and/or more stable foams. Using interferometry, the volume of liquid entrained in the film is measured for several different surfactant systems. The interfacial rheological properties of the surfactants are then related to the volume of fluid entrained in the film.