Aeration and dissolution behavior of oxygen nanobubbles in water

Hypothesis: Nanobubbles (NBs) in water elicit unique physicochemical and colloidal properties (e.g., high stability and longevity). Aeration kinetics and dissolution behavior of oxygen (O-2) NBs are assumed to be bubble size dependent. Experiments: As an indicator for aeration efficiency, volumetric mass transfer coefficient (K-L.a) was assessed by measuring the dissolved oxygen (DO) levels during aeration using O-2 NBs with different sizes. Mass transfer coefficient (K-L) was estimated by correlation analysis. Moreover, a modified Epstein-Plesset (EP) model was developed to predict the dissolution behavior by monitoring the DO and size changes during the dissolution of O-2 NBs in water. Findings: A higher rate of DO increase and a higher equilibrium DO level were both observed after aeration with NBs that present higher surface areas for the mass transfer of O-2 and a higher vapor pressure of O-2 to drive the partitioning equilibrium. Dissolution kinetics of O-2 NBs were highly dependent on the initial bubble size as indicated by the changes of bubble size and DO. Smaller NBs raised up DO faster, whereas larger NBs could lead to higher equilibrium DO levels. Moreover, the rate of DO decline and the quasi-steady DO levels both decreased when the dilution ratio increased, confirming that O-2 NBs dictates the DO level in water. Finally, the dissolving NBs may either swell or shrink according to the model prediction. (C) 2021 Elsevier Inc. All rights reserved.

Automated summary

This study investigates the aeration kinetics and dissolution behavior of oxygen nanobubbles (NBs) and their dependence on bubble size. The results show that larger NBs have higher oxygen mass transfer rates and equilibrium dissolution levels. The dissolution kinetics of oxygen NBs are influenced by the initial bubble size, with smaller bubbles dissolving faster and larger bubbles leading to higher equilibrium dissolution levels. Additionally, oxygen NBs determine the dissolved oxygen levels in water.