Litcius/Paper detail

Decrease in the Surface Tension of Nanobubble Dispersion in Water: Results of Surface Excess of Bulk Nanobubbles at Interfaces

Toru Tuziuti, Kyuichi Yasui, Wataru Kanematsu

2023Langmuir17 citationsDOI

Abstract

The effect of nanobubbles (NBs) on the surface tension of liquid was investigated by three methods of different measuring principles, pendant drop (PD), Wilhelmy, and du Noüy methods, over a wide range of number concentration of bulk NBs (BNBs). In all of the three methods, the surface tension decreased in proportion to the number concentration of BNBs and the proportional constant was different among the three methods. Such behavior was inferred to be caused by the surface excess of BNBs at the gas-liquid or solid-liquid interface. In the PD method, the hydrophobic interaction between BNBs and air around a drop seems to cause the surface excess of BNBs along the surface of water drops. It brings about a subtle change in its profile, resulting in the decrease in surface tension, which takes a time of hundreds of seconds. Meanwhile, in the Wilhelmy and du Noüy methods, electrostatic attractive force between BNBs and a plate or ring is a likely cause of surface excess at the solid-liquid interface, resulting in the instantaneous decrease in surface tension. This study also provides a practical methodology of comparison for surface tension of NB dispersion: surface tension shall be compared among different samples with the same measurement method. Especially in the PD method, retention time of droplets before measurement shall be the same among samples.

Topics & Concepts

Surface tensionWilhelmy plateDrop (telecommunication)Gibbs isothermChemistryDispersion (optics)London dispersion forceMaximum bubble pressure methodSessile drop techniqueSolid surfaceAnalytical Chemistry (journal)ChromatographyThermodynamicsChemical physicsOpticsvan der Waals forceMoleculeOrganic chemistryComputer scienceTelecommunicationsPhysicsMinerals Flotation and Separation TechniquesFluid Dynamics and MixingMetallurgical Processes and Thermodynamics