Pore-scale Study of Bio-mineral and Bio-gas Formations in Porous Media

abstract: The potential of using bio-geo-chemical processes for applications in geotechnical engineering has been widely explored in order to overcome the limitation of traditional ground improvement techniques. Biomineralization via urea hydrolysis, referred to as Microbial or Enzymatic Induced Carbonate Precipitation (MICP/EICP), has been shown to increase soil strength by stimulating precipitation of calcium carbonate minerals, bonding soil particles and filling the pores. Microbial Induced Desaturation and Precipitation (MIDP) via denitrification has also been studied for its potential to stabilize soils through mineral precipitation, but also through production of biogas, which can mitigate earthquake induced liquefaction by desaturation of the soil. Empirical relationships have been established, which relate the amount of products of these biochemical processes to the engineering properties of treated soils. However, these engineering properties may vary significantly depending on the biomineral and biogas formation mechanism and distribution patterns at pore-scale. This research focused on the pore-scale characterization of biomineral and biogas formations in porous media. The pore-scale characteristics of calcium carbonate precipitation via EICP and biogenic gas formation via MIDP were explored by visual observation in a transparent porous media using a microfluidic chip. For this purpose, an imaging system was designed and image processing algorithms were developed to analyze the experimental images and detect the nucleation and growth of precipitated minerals and formation and migration mechanisms of gas bubbles within the microfluidic chip. Statistical analysis was performed based on the processed images to assess the evolution of biomineral size distribution, the number of precipitated minerals and the porosity reduction in time. The resulting images from the biomineralization study were used in a numerical simulation to investigate the relation between the mineral distribution, porosity-permeability relationships and process efficiency. By comparing biogenic gas production with abiotic gas production experiments, it was found that the gas formation significantly affects the gas distribution and resulting degree of saturation. The experimental results and image analysis provide insight in the kinetics of the precipitation and gas formation processes and their resulting distribution and related engineering properties.Dissertation/ThesisDoctoral Dissertation Civil, Environmental and Sustainable Engineering 201

Role of Biominerals in Enhancing the Geophysical Response At Hydrocarbon Contaminated Sites

There are several source mechanisms by which microbial activity in the subsurface can change geophysical signatures. To date the source mechanisms generating the geophysical signatures in microbially active environments remain poorly understood. In this study, we investigated the link between the biogeochemical processes resulting in biotransformation of metallic iron mineral phases and the associated biogeophysical signatures. Hydrocarbon contaminated environments provide excellent laboratories for investigating iron mineral biotransformation. In particular, we investigated the magnetic susceptibility (MS) and the complex conductivity (CC) signatures of a hydrocarbon contaminated site near Bemidji, Minnesota. For the MS study, we investigated the changes in the MS response for cores retrieved from the site as well as down boreholes. The contaminated location revealed two enriched MS zones. The first MS lies within the hydrocarbon smear zone, which is limited to the zone of water table fluctuation with high concentrations of dissolved Fe(II) and organic carbon content. Magnetite and siderite were the dominant minerals formed during this process. However, magnetite was responsible for the bulk of MS changes. The second zone of MS enhancement lies within the vadose zone which is characterized by methane depletion suggesting that aerobic or anaerobic oxidation of methane is coupled to iron-reduction resulting in magnetite precipitation. For the CC work, we conducted laboratory CC measurements along four cores in addition to field CC survey. We found that the real (σ′) and imaginary (σ″) conductivity are higher for samples from within the oil plume especially within the smear zone compared to background uncontaminated samples. Using magnetite as an example of the biometallic minerals in the smear zone at the site, a clear increase in the σ″ response with increasing magnetite content was observed suggesting that the presence of bio-metallic mineral phases as well as electroactive Fe(II) within the smear zone impacts the imaginary conductivity. Our results suggest that the biogeochemical processes leading to the precipitation of metallic iron mineral phases impacts the geophysical signatures at hydrocarbon contaminated sites undergoing active biodegradation. These bio-metallic minerals (e.g., magnetite) provide us with another source mechanism which has not been considered in previous studies. Therefore, the recognition of the zone of enriched bio-metallic iron mineral phases within the water table fluctuating zone calls for a reevaluation of biogeophysical signatures observed at hydrocarbon contaminated sites commonly attributed to an enhancement of pore water conductivity related to the production of metabolic byproducts.Geolog