University of Illinois Urbana-Champaign

Investigating uranium mobility using groundwater 238U/235U data and a reactive transport model

Bizjack, Matthew Thomas

Content Files
BIZJACK-THESIS-2016.pdf

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https://hdl.handle.net/2142/90833

Description

Title
Investigating uranium mobility using groundwater 238U/235U data and a reactive transport model
Author(s)
Bizjack, Matthew Thomas
Issue Date
2016-04-26
Director of Research (if dissertation) or Advisor (if thesis)
  • Johnson, Thomas M.
  • Druhan, Jennifer L
Department of Study
Geology
Discipline
Geology
Degree Granting Institution
University of Illinois at Urbana-Champaign
Degree Name
M.S.
Degree Level
Thesis
Date of Ingest
2016-07-07T20:35:17Z
Keyword(s)
  • uranium
  • bioremediation
  • reactive transport
  • stable isotopes
  • CrunchTope
  • rate-limited desorption
Abstract
"In order to better understand chemical reactions affecting the subsurface transport of the widespread contaminant uranium (U), we present a numerical reactive transport model which explicitly incorporates variations in the 238U/235U isotope ratio. Bioremediation, the microbial reductive immobilization of aqueous U(VI) to solid U(IV), has been proposed as a U remediation technique. Both laboratory and field experiments have demonstrated that microbial reduction of U(VI) alters 238U/235U, producing a 238U-enriched solid U(IV) product. Other major U reactive transport processes do not fractionate isotopes significantly. This suggests the potential to quantify the extent of bioreduction occurring in groundwater containing U using 238U/235U as a compliment to the information gained through U concentration measurements. A recent study of a U bioremediation experiment at a contaminated DOE site in Rifle, Colorado, applied Rayleigh distillation models to quantify U stable isotope fractionation observed during biostimulation via acetate amendment. These simplified models have known inaccuracies and do not incorporate the complex hydrologic and geochemical aspects of the site. To more accurately interpret these measured U isotope ratios, we present a multi-component reactive transport model capable of reproducing observed trends in geochemistry and 238U/235U ratios from the field experiment. Model results suggest that the rate-limited transport properties of U in the Rifle aquifer are governed by the presence of low-permeability regions in the modeling domain and that these zones are responsible for the suggested ""memory"" effect observed in previous U isotope studies at this site. Accurate modeling of observed U isotope ratios is crucial to their use as a method of tracking bioremediation, and this study serves to advance the quantitative application of isotope systems in reactive transport."
Graduation Semester
2016-05
Type of Resource
text
Permalink
http://hdl.handle.net/2142/90833
Copyright and License Information
Copyright 2016 Matthew Bizjack

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