Flow field dynamics and high ethanol content in gasohol blends enhance BTEX migration and biodegradation in groundwater

Gasohol spills may easily descend through the soil column down and impact sensitive receptors as contaminants dissolve into the groundwater. Gasoline formulations are commonly blended with ethanol to alleviate environmental and economic issues associated with fossil fuels. However, the amount of eth...

Full description

Saved in:
Bibliographic Details
Published inJournal of contaminant hydrology Vol. 222; pp. 17 - 30
Main Authors Rama, Fabrizio, Ramos, Débora Toledo, Müller, Juliana Braun, Corseuil, Henry Xavier, Miotliński, Konrad
Format Journal Article
LanguageEnglish
Published Netherlands Elsevier B.V 01.04.2019
Subjects
Biodegradation rate
BTEX
Dissolution
Plume spreading
Transient flow
Transport
Biodegradation rate
Transient flow
BTEX
Transport
Dissolution
Plume spreading
Online AccessGet full text

Cover

More Information
Summary:Gasohol spills may easily descend through the soil column down and impact sensitive receptors as contaminants dissolve into the groundwater. Gasoline formulations are commonly blended with ethanol to alleviate environmental and economic issues associated with fossil fuels. However, the amount of ethanol added to gasoline and the groundwater hydraulic regime can significantly affect BTEX plume dynamics and lifespan. In this study, two long-term (5 and 10 years) field-scale gasohol releases with ethanol contents of 85% (E85) and 24% (E24), respectively, were assessed to discern the different dynamics undergone by gasohol blends. Statistical, geochemical, microbiological and trend approaches were employed to estimate the influence of groundwater flow variations on ethanol and dissolved BTEX transport, and the associated biodegradation rates of different gasohol blend spills. Ethanol and BTEX groundwater flow were quantified in terms of breakthrough curve characteristics, plume centroid positions and spreading, source depletion and mass degradation rates. In addition, bromide migration was evaluated to address the contribution of flow-driven dissolution. Results revealed that the high amount of ethanol along with a fast and dynamic flow exerted a flushing behavior that enhanced BTEX dissolution, migration (vertical and horizontal) and concentrations in groundwater. The higher amount of ethanol in E85 enhanced BTEX dissolution (and bioavailability) relative to E24 site and led to faster biodegradation rates, which can be explained by the cosolvency effect and metabolic flux dilution. Therefore, flow field dynamics and high ethanol content in gasohol blends enhance BTEX migration and biodegradation in gasohol-contaminated sites. The balance of these factors is crucial to determine fate and transport of contaminants in field sites. These findings suggest that hydraulic regime should be spatially and temporally characterized to support decisions on appropriate monitoring plan and remedial strategies for gasohol spills.
ISSN:0169-7722
1873-6009
DOI:10.1016/j.jconhyd.2019.01.003