2026-05-24T09:37:15Zhttps://keep.lib.asu.edu/oai/requestoai:keep.lib.asu.edu:node-1524382024-12-20T18:25:12Zoai_pmh:alloai_pmh:repo_items152438
https://hdl.handle.net/2286/R.I.24781
http://rightsstatements.org/vocab/InC/1.0/
All Rights Reserved
2014
xiii, 161 p. : col. ill
Doctoral Dissertation
Academic theses
Text
eng
Ontiveros-Valencia, Aura
Rittmann, Bruce E.
Krajmalnik-Brown, Rosa
Torres, Cesar I.
Arizona State University
Partial requirement for: Ph. D., Arizona State University, 2014
Includes bibliographical references (p. 145-161)
Field of study: Sustainability
Water contamination with nitrate (NO3−) (from fertilizers) and perchlorate (ClO4−) (from rocket fuel and explosives) is a widespread environmental problem. I employed the Membrane Biofilm Reactor (MBfR), a novel bioremediation technology, to treat NO3− and ClO4− in the presence of naturally occurring sulfate (SO42−). In the MBfR, bacteria reduce oxidized pollutants that act as electron acceptors, and they grow as a biofilm on the outer surface of gas-transfer membranes that deliver the electron donor (hydrogen gas, (H2). The overarching objective of my research was to achieve a comprehensive understanding of ecological interactions among key microbial members in the MBfR when treating polluted water with NO3− and ClO4− in the presence of SO42−. First, I characterized competition and co-existence between denitrifying bacteria (DB) and sulfate-reducing bacteria (SRB) when the loading of either the electron donor or electron acceptor was varied. Then, I assessed the microbial community structure of biofilms mostly populated by DB and SRB, linking structure with function based on the electron-donor bioavailability and electron-acceptor loading. Next, I introduced ClO4− as a second oxidized contaminant and discovered that SRB harm the performance of perchlorate-reducing bacteria (PRB) when the aim is complete ClO4− destruction from a highly contaminated groundwater. SRB competed too successfully for H2 and space in the biofilm, forcing the PRB to unfavorable zones in the biofilm. To better control SRB, I tested a two-stage MBfR for total ClO4− removal from a groundwater highly contaminated with ClO4−. I document successful remediation of ClO4− after controlling SO4 2− reduction by restricting electron-donor availability and increasing the acceptor loading to the second stage reactor. Finally, I evaluated the performance of a two-stage pilot MBfR treating water polluted with NO3− and ClO4−, and I provided a holistic understanding of the microbial community structure and diversity. In summary, the microbial community structure in the MBfR contributes to and can be used to explain/predict successful or failed water bioremediation. Based on this understanding, I developed means to manage the microbial community to achieve desired water-decontamination results. This research shows the benefits of looking "inside the box" for "improving the box".
Environmental engineering
Molecular Biology
microbial community structure
Nitrates
Perchlorates
pyrosequencing
qPCR
Sulfates
Sulfate-reducing bacteria
Biofilms
Membrane reactors
Water--Purification--Nitrogen removal.
Water--Purification--Perchlorate removal.
Ecological interactions among nitrate-, perchlorate-, and sulfate-reducing bacteria in hydrogen-fed biofilm reactors