Surface Forces and Interaction Mechanisms of Emulsion
Drops and Gas Bubbles in Complex Fluids
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Abstract
The interactions
of emulsion drops and gas bubbles in complex fluids
play important roles in a wide range of biological and technological
applications, such as programmable drug and gene delivery, emulsion
and foam formation, and froth flotation of mineral particles. In this
feature article, we have reviewed our recent progress on the quantification
of surface forces and interaction mechanisms of gas bubbles and emulsion
drops in different material systems by using several complementary
techniques, including the drop/bubble probe atomic force microscope
(AFM), surface forces apparatus (SFA), and four-roll mill fluidic
device. These material systems include the bubble–self-assembled
monolayer (SAM), bubble–polymer, bubble–superhydrophobic
surface, bubble–mineral, water-in-oil and oil-in-water emulsions
with interface-active components in oil production, and oil/water
wetting on polyelectrolyte surfaces. The bubble probe AFM combined
with reflection interference contrast microscopy (RICM) was applied
for the first time to simultaneously quantify the interaction forces
and spatiotemporal evolution of a confined thin liquid film between
gas bubbles and solid surfaces with varying hydrophobicity. The nanomechanical
results have provided useful insights into the fundamental interaction
mechanisms (e.g., hydrophobic interaction in aqueous media) at gas/water/solid
interfaces, the stabilization/destabilization mechanisms of emulsion
drops, and oil/water wetting mechanisms on solid surfaces. A long-range
hydrophilic attraction was found between water and polyelectrolyte
surfaces in oil, with the strongest attraction for polyzwitterions,
contributing to their superior water wettability in oil and self-cleaning
capability of oil contamination. Some remaining challenges and future
research directions are discussed and provided