Hydrodynamic Treadmill Reveals Reduced Rising Speeds of Oil Droplets Deformed by Marine Bacteria

In marine environments, microscopic droplets of oil can be transported over large distances in the water column. Bacterial growth on the droplets’ surface can deform the oil–water interface to generate complex shapes and significantly enlarge droplets. Understanding the fate of spilled oil droplets...

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Bibliographic Details
Published in:Environmental science & technology 2023-09, Vol.57 (37), p.14082-14089
Main Authors: Hickl, Vincent, Pamu, Hima Hrithik, Juarez, Gabriel
Format: Article
Language:English
Subjects:
Bacteria
Biofilms
Deformation effects
Drag
Droplets
Fluorescence
Fluorescence microscopy
Marine environment
Marine organisms
Occurrence, Fate, and Transport of Aquatic and Terrestrial Contaminants
Oil spills
Oils & fats
Treadmills
Water circulation
Water column
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Summary:In marine environments, microscopic droplets of oil can be transported over large distances in the water column. Bacterial growth on the droplets’ surface can deform the oil–water interface to generate complex shapes and significantly enlarge droplets. Understanding the fate of spilled oil droplets requires bridging these length scales and determining how microscale processes affect the large-scale transport of oil. Here, we describe an experimental setup, the hydrodynamic treadmill, developed to keep rising oil droplets stationary in the lab frame for continuous and direct observation. Oil droplets with radii 10 < R < 100 μm were colonized and deformed by bacteria over several days before their effective rising speeds were measured. The rising speeds of deformed droplets were significantly slower than those of droplets without bacteria. This decrease in rising speed is understood by an increase in drag force and a decrease in buoyancy as a result of bio-aggregate formation at the droplet surface. Additionally, we found sinking bio-aggregate particles of oil and bacterial biofilms and quantified their composition using fluorescence microscopy. Our experiments can be adapted to further study the interactions between oil droplets and marine organisms and could significantly improve our understanding of the transport of hydrocarbons and complex aggregates.
ISSN:0013-936X
1520-5851
DOI:10.1021/acs.est.3c04902