Nuclear magnetic resonance studies of biofilm - porous media systems

dc.contributor.advisorChairperson, Graduate Committee: Sarah L. Codd; Joseph D. Seymour (co-chair)en
dc.contributor.authorKirkland, Catherine Mullinnixen
dc.contributor.otherSarah L. Codd was a co-author of the article, 'Low-field borehole NMR applications in the near subsurface environment' submitted to the journal 'Vadose zone journal' which is contained within this thesis.en
dc.contributor.otherRandy Hiebert, Adrienne Phillips, Elliot Grunewald, David O. Walsh, Joseph D. Seymour and Sarah L. Codd were co-authors of the article, 'Biofilm detection in a model well-bore environment using low-field NMR' in the journal 'Groundwater monitoring and remediation' which is contained within this thesis.en
dc.contributor.otherMaria P. Herrling, Randy Hiebert, Andrew T. Bender, Elliot Grunewald, David O. Walsh and Sarah L. Codd were co-authors of the article, 'In-situ detection of subsurface biofilm using low-field NMR - a field study' in the journal 'Environmental science and technology' which is contained within this thesis.en
dc.contributor.otherSam Zanetti, Elliot Grunewald, David O. Walsh, Sarah L. Codd and Adrienne J. Phillips were co-authors of the article, 'Detecting microbially-induced calcite precipitation (MICP) in a model well-bore using downhole low-field NMR' in the journal 'Environmental science and technology' which is contained within this thesis.en
dc.contributor.otherJessica Weisbrodt, Catherine M. Kirkland, Nathan H. Williamson, Susanne Lackner, Sarah L. Codd, Joseph D. Seymour, Gisela Guthausen and Harald Horn were co-authors of the article, 'NMR investigation of water diffusion in different biofilm structures' submitted to the journal 'Biotechnology and bioengineering' which is contained within this thesis.en
dc.date.accessioned2018-02-26T17:33:25Z
dc.date.available2018-02-26T17:33:25Z
dc.date.issued2017en
dc.description.abstractNuclear magnetic resonance (NMR) allows for in-situ non-invasive studies of opaque systems over a wide range of length and time scales, making the method uniquely suited to studies of biofilms and porous media. The research comprising this thesis uses NMR to explore biophysical, chemical, and transport properties within heterogeneous porous media systems at both a macro- and micro-scale. The macro-scale projects validate a low-field borehole NMR instrument to monitor field-scale environmental engineering applications like subsurface biofilms and microbially-induced calcite precipitation (MICP). Subsurface biofilms are central to bioremediation of chemical contaminants in soil and groundwater whereby micro-organisms degrade or sequester environmental pollutants like nitrate, hydrocarbons, chlorinated solvents and heavy metals. When composed of ureolytic microbes, subsurface biofilms can also induce calcite precipitation. MICP has engineering applications that include soil stabilization and subsurface barriers, as well as sealing of cap rocks and well-bore regions for carbon dioxide sequestration. To meet the design goals of these beneficial applications, subsurface biofilms and MICP must be monitored over space and time - a challenging task with traditional methods. The low-field borehole NMR tool recorded changes in the T 2 relaxation distribution where enhanced relaxation indicated biofilm accumulation in a sand bioreactor and in subsurface soil. Additionally, the tool was able to detect MICP in a sand bioreactor. The changed mineral surface of the sand lead to an increase in T 2 relaxation times. The complementary high-field NMR project investigated micro-scale internal structures and mass transport within biofilm granules used for wastewater treatment. Granular sludge, composed of spherical aggregates of biofilm grown without a carrier, is an innovative biological treatment method with the potential to vastly reduce the cost of wastewater treatment without sacrificing efficiency. Large gaps remain, however, in our understanding of the fundamental formation mechanisms and the factors that control granule activity and stability. Magnetic resonance imaging (MRI) identified heterogeneous internal structures within aerobic granular sludge where relaxation rates and diffusion coefficients vary. Ultimately, these results will help improve modeling for optimization of granular sludge wastewater treatment process design.en
dc.identifier.urihttps://scholarworks.montana.edu/handle/1/13478en
dc.language.isoenen
dc.publisherMontana State University - Bozeman, College of Engineeringen
dc.rights.holderCopyright 2017 by Catherine Mullinnix Kirklanden
dc.subject.lcshNuclear magnetic resonanceen
dc.subject.lcshBiofilmsen
dc.subject.lcshMagnetic resonance imagingen
dc.subject.lcshBioremediationen
dc.subject.lcshPrecipitation (Chemistry)en
dc.titleNuclear magnetic resonance studies of biofilm - porous media systemsen
dc.typeDissertationen
mus.data.thumbpage276en
thesis.degree.committeemembersMembers, Graduate Committee: Ellen G. Lauchnor; Elliot Grunewald.en
thesis.degree.departmentChemical & Biological Engineering.en
thesis.degree.genreDissertationen
thesis.degree.namePhDen
thesis.format.extentfirstpage1en
thesis.format.extentlastpage306en

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