Theoretical Insight into the Biodegradation of Solitary Oil Microdroplets Moving through a Water Column

In the aftermath of oil spills in the sea, clouds of droplets drift into the seawater column and are carried away by sea currents. The fate of the drifting droplets is determined by natural attenuation processes, mainly dissolution into the seawater and biodegradation by oil-degrading microbial comm...

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Main Authors: George E. Kapellos, Christakis A. Paraskeva, Nicolas Kalogerakis, Patrick S. Doyle
Format: Article
Language:English
Published: MDPI AG 2018-02-01
Series:Bioengineering
Subjects:
Online Access:http://www.mdpi.com/2306-5354/5/1/15
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spelling doaj-484d97854b2f4c96a0f8b774f21645042020-11-24T23:25:20ZengMDPI AGBioengineering2306-53542018-02-01511510.3390/bioengineering5010015bioengineering5010015Theoretical Insight into the Biodegradation of Solitary Oil Microdroplets Moving through a Water ColumnGeorge E. Kapellos0Christakis A. Paraskeva1Nicolas Kalogerakis2Patrick S. Doyle3Department of Chemical Engineering, Massachusetts Institute of Technology, Cambridge, MA 02139, USADepartment of Chemical Engineering, University of Patras, 26504 Rion Achaia, GreeceSchool of Environmental Engineering, Technical University of Crete, 73100 Chania, GreeceDepartment of Chemical Engineering, Massachusetts Institute of Technology, Cambridge, MA 02139, USAIn the aftermath of oil spills in the sea, clouds of droplets drift into the seawater column and are carried away by sea currents. The fate of the drifting droplets is determined by natural attenuation processes, mainly dissolution into the seawater and biodegradation by oil-degrading microbial communities. Specifically, microbes have developed three fundamental strategies for accessing and assimilating oily substrates. Depending on their affinity for the oily phase and ability to proliferate in multicellular structures, microbes might either attach to the oil surface and directly uptake compounds from the oily phase, or grow suspended in the aqueous phase consuming solubilized oil, or form three-dimensional biofilms over the oil–water interface. In this work, a compound particle model that accounts for all three microbial strategies is developed for the biodegradation of solitary oil microdroplets moving through a water column. Under a set of educated hypotheses, the hydrodynamics and solute transport problems are amenable to analytical solutions and a closed-form correlation is established for the overall dissolution rate as a function of the Thiele modulus, the Biot number and other key parameters. Moreover, two coupled ordinary differential equations are formulated for the evolution of the particle size and used to investigate the impact of the dissolution and biodegradation processes on the droplet shrinking rate.http://www.mdpi.com/2306-5354/5/1/15biofilmcrude oilmodelingoil spilldroplet clouddroplet dissolutiondroplet biodegradationSherwood numbermass transfercompound droplet model
collection DOAJ
language English
format Article
sources DOAJ
author George E. Kapellos
Christakis A. Paraskeva
Nicolas Kalogerakis
Patrick S. Doyle
spellingShingle George E. Kapellos
Christakis A. Paraskeva
Nicolas Kalogerakis
Patrick S. Doyle
Theoretical Insight into the Biodegradation of Solitary Oil Microdroplets Moving through a Water Column
Bioengineering
biofilm
crude oil
modeling
oil spill
droplet cloud
droplet dissolution
droplet biodegradation
Sherwood number
mass transfer
compound droplet model
author_facet George E. Kapellos
Christakis A. Paraskeva
Nicolas Kalogerakis
Patrick S. Doyle
author_sort George E. Kapellos
title Theoretical Insight into the Biodegradation of Solitary Oil Microdroplets Moving through a Water Column
title_short Theoretical Insight into the Biodegradation of Solitary Oil Microdroplets Moving through a Water Column
title_full Theoretical Insight into the Biodegradation of Solitary Oil Microdroplets Moving through a Water Column
title_fullStr Theoretical Insight into the Biodegradation of Solitary Oil Microdroplets Moving through a Water Column
title_full_unstemmed Theoretical Insight into the Biodegradation of Solitary Oil Microdroplets Moving through a Water Column
title_sort theoretical insight into the biodegradation of solitary oil microdroplets moving through a water column
publisher MDPI AG
series Bioengineering
issn 2306-5354
publishDate 2018-02-01
description In the aftermath of oil spills in the sea, clouds of droplets drift into the seawater column and are carried away by sea currents. The fate of the drifting droplets is determined by natural attenuation processes, mainly dissolution into the seawater and biodegradation by oil-degrading microbial communities. Specifically, microbes have developed three fundamental strategies for accessing and assimilating oily substrates. Depending on their affinity for the oily phase and ability to proliferate in multicellular structures, microbes might either attach to the oil surface and directly uptake compounds from the oily phase, or grow suspended in the aqueous phase consuming solubilized oil, or form three-dimensional biofilms over the oil–water interface. In this work, a compound particle model that accounts for all three microbial strategies is developed for the biodegradation of solitary oil microdroplets moving through a water column. Under a set of educated hypotheses, the hydrodynamics and solute transport problems are amenable to analytical solutions and a closed-form correlation is established for the overall dissolution rate as a function of the Thiele modulus, the Biot number and other key parameters. Moreover, two coupled ordinary differential equations are formulated for the evolution of the particle size and used to investigate the impact of the dissolution and biodegradation processes on the droplet shrinking rate.
topic biofilm
crude oil
modeling
oil spill
droplet cloud
droplet dissolution
droplet biodegradation
Sherwood number
mass transfer
compound droplet model
url http://www.mdpi.com/2306-5354/5/1/15
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AT nicolaskalogerakis theoreticalinsightintothebiodegradationofsolitaryoilmicrodropletsmovingthroughawatercolumn
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