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Simultaneous Diesel and Oxygen Transfer Rate on the Production of an Oil-degrading Consortium in an Airlift Bioreactor: High-dispersed Phase Concentration

  • Abhishek Dutta ORCID logo , Sergio Valdivia-Rivera ORCID logo and Manuel Alejandro Lizardi-Jiménez ORCID logo EMAIL logo
Published/Copyright: April 12, 2018
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International Journal of Chemical Reactor Engineering
From the journal International Journal of Chemical Reactor Engineering Volume 16 Issue 10

Abstract

The aim of this study was to simultaneously evaluate diesel transfer rate (DTR) and oxygen transfer rate (OTR) on the production of an oil-degrading consortium in a three-phase airlift bioreactor (ALB) working at high hydrocarbon phase concentration with the purpose of determine whether the oxygen transfer rate is increased or diminished by an increase in the oil-phase concentration. Increase in hydrocarbon concentration allows an increase in DTR and a consequently higher DTR/OTR ratio thus avoiding hydrocarbon mass transfer limitations. This study demonstrates evidence that at high diesel concentrations, the main carbon fate is the production of biosurfactants.

Keywords: Airlift bioreactor; diesel transfer rate; oil-degrading consortium; oxygen transfer rate

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Received: 2017-10-30
Revised: 2018-03-13
Accepted: 2018-03-19
Published Online: 2018-04-12

© 2018 Walter de Gruyter GmbH, Berlin/Boston

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  3. Parametric Mathematical Modelling of Cristal Violet Dye Electrochemical Oxidation Using a Flow Electrochemical Reactor with BDD and DSA Anodes in Sulfate Media
  4. Photocatalytic Degradation of Caffeine in a Solar Reactor System
  5. Effect of Biomass Concentration on Oxygen Mass Transfer, Power Consumption, Interfacial Tension and Hydrodynamics in a Multiphase Partitioning Bioreactor
  6. Modeling and Hydraulic Characterization of a Filter-Press-Type Electrochemical Reactor by Using Residence Time Distribution Analysis and Hydraulic Indices
  7. Waste-to-energy: Coupling Waste Treatment to Highly Efficient CHP
  8. The Effect of Sn Content in a Pt/KIT-6 Catalyst Over its Performance in the Dehydrogenation of Propane
  9. Dehydrogenation of Propane to Propylene with Highly Stable Catalysts of Pt-Sn Supported Over Mesoporous Silica KIT-6
  10. Simultaneous Diesel and Oxygen Transfer Rate on the Production of an Oil-degrading Consortium in an Airlift Bioreactor: High-dispersed Phase Concentration
  11. Green Practices with Renewable Distributed Generation Technology in India
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https://doi.org/10.1515/ijcre-2017-0206
Keywords for this article
Airlift bioreactor; diesel transfer rate; oil-degrading consortium; oxygen transfer rate

Articles in the same Issue

  2. Preface to the Special Issue Dedicated to the International Energy Conference, IEC 2017: Energy and its Development in the Twenty-First Century: A globalized vision
  3. Parametric Mathematical Modelling of Cristal Violet Dye Electrochemical Oxidation Using a Flow Electrochemical Reactor with BDD and DSA Anodes in Sulfate Media
  4. Photocatalytic Degradation of Caffeine in a Solar Reactor System
  5. Effect of Biomass Concentration on Oxygen Mass Transfer, Power Consumption, Interfacial Tension and Hydrodynamics in a Multiphase Partitioning Bioreactor
  6. Modeling and Hydraulic Characterization of a Filter-Press-Type Electrochemical Reactor by Using Residence Time Distribution Analysis and Hydraulic Indices
  7. Waste-to-energy: Coupling Waste Treatment to Highly Efficient CHP
  8. The Effect of Sn Content in a Pt/KIT-6 Catalyst Over its Performance in the Dehydrogenation of Propane
  9. Dehydrogenation of Propane to Propylene with Highly Stable Catalysts of Pt-Sn Supported Over Mesoporous Silica KIT-6
  10. Simultaneous Diesel and Oxygen Transfer Rate on the Production of an Oil-degrading Consortium in an Airlift Bioreactor: High-dispersed Phase Concentration
  11. Green Practices with Renewable Distributed Generation Technology in India
  12. Carcinogenic Hydrocarbon Pollution in Quintana Roo’s Sinkholes: Biotechnology for Remediation and Social Participation for Prevention
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