Brill E-Books

 Bubble and Drop Interfaces

Contents

• • Preliminary Material (i-viii)   (135K)
    • Jump to section:
    • Progress In Colloid And Interface Science (PCIS)
    • Content
  • Introduction Drops And Bubbles As Effective Tools For Interfacial Studies (1-6) by R. Miller and L. Liggieri   (262K)
    • Jump to section:
    • A. General Introduction
    • B. Basic Drop And Bubble Methods
    • C. Drop Methodologies With Particular Applications
    • D. Drop–Drop And Bubble–Bubble Interactions In Foams And Emulsions
    • E. Outlook
    • F. References
  • Determination Of Interfacial Properties By The Pendant Drop Tensiometry: Optimisation Of Experimental And Calculation Procedures (7-38) by G. Loglio, P. Pandolfini, L. Liggieri, A.V. Makievski and F. Ravera   (1M)
    • Jump to section:
    • A. Introduction
    • B. Fine Tuning Of Optical Calibration
    • C. Combination Of Profile-Analysis Tensiometry With Capillary-Pressure Tensiometry
    • D. Analysis Of Optical Noisy Images
    • E. Study Of Interfacial Responses To Perturbations Of Interfacial Area
    • F. Summary
    • G. Acknowledgements
    • H. References
  • Advances In Calculation Methods For The Determination Of Surface Tensions In Drop Profile Analysis Tensiometry (39-60) by S.A. Zholob, A.V. Makievski, R. Miller and V.B. Fainerman   (292K)
    • Jump to section:
    • A. Introduction
    • B. Experimental Aspects Of Drop Profile Analysis Tensiometry
    • C. Improvement In The Extraction Of Profile Coordinates
    • D. Initial Estimation Of Adjustable Parameters
    • E. Transformation Of The Gauss–Laplace Equation To Avoid Interpolation
    • F. Experimental Results
    • G. Conclusion
    • H. Acknowledgements
    • I. References
  • Axisymmetric Drop Shape Analysis With Anisotropic Interfacial Stresses: Deviations From The Young-Laplace Equation (61-74) by J.K. Ferri and P.A.L. Fernandes   (415K)
    • Jump to section:
    • A. Introduction
    • B. Theory
    • C. Results And Discussion
    • D. Conclusions And Prospectus
    • E. Acknowledgements
    • F. References
  • Maximum Bubble Pressure Tensiometry: Theory, Analysis Of Experimental Constrains And Applications (75-118) by V.B. Fainerman and R. Miller   (753K)
    • Jump to section:
    • A. Introduction
    • B. The Optimum Design Of Bubble Pressure Tensiometers And Measuring Procedure
    • C. Surface Tension Determination
    • D. Bubble Time And Its Constituents
    • E. Analysis Of Experimental Constrains
    • F. Examples Of Experimental Results
    • G. Conclusions
    • H. List Of Symbols
    • I. References
  • Drop Volume Tensiometry (119-142) by A. Javadi, V.B. Fainerman and R. Miller   (470K)
    • Jump to section:
    • A. Historical Survey
    • B. The Drop Volume Experiment
    • C. Effect Of Hydrodynamics On Measured Drop Volumes
    • D. Theory Of Surfactant Adsorption At The Surface Of Growing Drops
    • E. Experimental Results
    • F. Summary And Conclusions
    • G. Acknowledgements
    • H. List Of Symbols
    • I. References
  • Studies In Capillary Pressure Tensiometry And Interfacial Dilational Rheology (143-178) by V.I. Kovalchuk, F. Ravera, L. Liggieri, G. Loglio, A. Javadi, N.M. Kovalchuk and J. Krägel   (1M)
    • Jump to section:
    • A. Introduction
    • B. Experimental Techniques For Capillary Pressure Tensiometry And Dilational Rheology
    • C. Theoretical Basis Of Capillary Pressure Tensiometry
    • D. Critical Aspects In Capillary Pressure Tensiometry
    • E. Capillary Pressure Instruments For Space Experiments
    • F. Experimental Results
    • G. Conclusions
    • H. Acknowledgements
    • I. References
  • Direct Determination Of Protein And Surfactant Adsorption By Drop And Bubble Profile Tensiometry (179-194) by V.B. Fainerman and R. Miller   (683K)
    • Jump to section:
    • A. Introduction
    • B. Experiments And Determination Of Adsorption
    • C. Results And Discussion
    • D. Conclusions
    • E. Acknowledgements
    • F. References
  • Coaxial Capillary Pendant Drop Experiments With Subphase Exchange (195-222) by J.K. Ferri, A.D. Cramer, C. Kotsmar and R. Miller   (2M)
    • Jump to section:
    • A. Introduction
    • B. A New Drop Methodology: Coaxial Capillary Pendant Drop (CCPD) Method
    • C. Surfactant And Small Amphiphile Exchange
    • D. Polymers, Biomacromolecules And Mixed Systems
    • E. Ultrathin Surface Composites And Membranes
    • F. Other Applications
    • G. Acknowledgements
    • H. References
  • Wetting Dynamics Of Aqueous Solutions On Solid Surfaces (223-242) by V. Dutschk   (968K)
    • Jump to section:
    • A. Essentials Of Wetting
    • B. Wetting Dynamics
    • C. Dynamic Contact Angle Measurements
    • D. Summary
    • E. Acknowledgements
    • F. References
  • Bubbles Rising In Solutions; Local And Terminal Velocities, Shape Variations And Collisions With Free Surface (243-292) by K. Malysa, J. Zawala, M. Krzan and M. Krasowska   (1M)
    • Jump to section:
    • A. Introduction
    • B. Bubble Formation
    • C. Initial Acceleration Of The Bubble
    • D. Local Velocity Profiles
    • E. Inducement Of Dynamic Structure Of The Adsorption Layer (DAL) On The Rising Bubble
    • F. Terminal Velocity Of The Bubbles
    • G. Bubble Collisions With Liquid/Gas Interface
    • H. Bubble Velocity As A Tool To Monitor Organic Contaminations In Water
    • I. List Of Symbols And Abbreviations
    • J. References
  • Surface Tension Measurement Of Polymer Melts In Supercritical Fluids (293-324) by H. Wei, R.B. Thompson, C.B. Park and P. Chen   (588K)
    • Jump to section:
    • A. Introduction
    • B. Experimental Section
    • C. Surface Tension Of Polystyrene (PS) In Supercritical CO
    • D. Surface Tension Of High Density Polyethylene (HDPE) In Supercritical N
    • E. Conclusions
    • F. Acknowledgements
    • G. References
  • Accumulation Of Surfactant In The Top Foam Layer Caused By Ruptured Foam Films (325-350) by S.S. Dukhin, V.I. Kovalchuk, E.V. Aksenenko and R. Miller   (450K)
    • Jump to section:
    • A. Introduction
    • B. Qualitative Mechanism Of Surfactant Accumulation In The Top Bubble Layer Of A Foam Caused By External Film Rupture
    • C. Estimation Of Surfactant Loss
    • D. Capillary Hydrodynamic Phenomena Following The Rupture Of A Single External Foam Film
    • E. Surfactant Accumulation Due To Multiple Ruptures Of External Films
    • F. SAFT And Surface Rheology
    • G. Conditions For The Onset Of SAFT
    • H. Droplet Formation During Breakage Of Foam Films And Its Influence On Surfactant Accumulation
    • I. Discussion And Conclusions
    • J. Appendix
    • K. Acknowledgements
    • L. References
  • Particle-Bubble Interaction In Flotation (351-384) by A.V. Nguyen   (918K)
    • Jump to section:
    • A. Introduction
    • B. Collision
    • C. Attachment
    • D. Stability And Detachment
    • E. Conclusions
    • F. Acknowledgement
    • G. References
  • Experimental Observation Of Drop-Drop Coalescence In Liquid-Liquid Systems: Instrument Design And Features (385-400) by G. Loglio, P. Pandolfini, F. Ravera, R. Pugh, A.V. Makievski, A. Javadi and R. Miller   (971K)
    • Jump to section:
    • A. Introduction
    • B. Importance Of Drop–Drop Coalescence
    • C. The Drop/Bubble Micro-Manipulator (DBMM)
    • D. Examples Of Application Results
    • E. Summary
    • F. Acknowledgements
    • G. References
  • The Tensiograph Platform For Optical Measurement (401-480) by N.D. McMillan, S.R.P. Smith, M. O’ Neill, K. Tiernan, D. Morrin, P. Pringuet, G. Doyle, B. O’Rourke, A.C. Bertho, J. Hammond, D.D.G. McMillan, S. Riedel, D. Carbery, A. Augousti, N. Wüstneck, R. Wüstneck, F. Colin, P. Hennerbert, G. Pottecher, D. Kennedy and N. Barnett   (2M)
    • Jump to section:
    • A. Introduction
    • B. Drop Shape/Tensiotrace Model
    • C. Drop Spectroscopy
    • D. Refractive Index-Rainbow Peak —Bulk Properties
    • E. Surface Tension —Drop Period And Tensiopeak Period Relationship
    • F. Calibration Standards For Tensiographic Fingerprinting
    • G. Conclusion
    • H. References
  • Emulsification With Micro-Structured Membranes And Micro-Engineered Systems (481-502) by R.M. Boom and C.G.P.H. Schroën   (796K)
    • Jump to section:
    • A. Emulsification With Membranes And Micro-Engineered Systems
    • B. Droplet Snap-Off Induced By Localized Shear Flow
    • C. Droplet Snap-Off Induced By Interfacial Tension Effects
    • D. Premix Membrane Emulsification
    • E. Coflowing Systems
    • F. Concluding Remarks
    • G. Acknowledgement
    • H. References
  • Manipulation Of Droplets Onto A Planar Interface (503-520) by T. Gilet, D. Terwagne, N. Vandewalle and S. Dorbolo   (591K)
    • Jump to section:
    • A. Introduction
    • B. Delayed Coalescence On A Planar Interface At Rest
    • C. Delayed Coalescence On A Vertically Vibrated Bath
    • D. Partial Coalescence
    • E. Influence Of Viscosities
    • F. Mixing Droplets Together
    • G. Control Of The Partial Coalescence With Bouncing
    • H. Conclusion
    • I. Acknowledgements
    • J. References
  • Interfacial Mass Transfer Of Growing Drops In Liquid-Liquid Systems (521-550) by A. Javadi, D. Bastani, M. Taeibi-Rahni, M. Karbaschi and R. Miller   (1M)
    • Jump to section:
    • A. Introduction
    • B. Hydrodynamics Of Drop Formation
    • C. Interfacial Mass Transfer Of Growing Drops
    • D. Conclusion
    • E. Acknowledgements
    • F. List Of Symbols
    • G. References
  • Subject Index (551-558)   (97K)