Widespread use of halogenated organic compounds for commercial and industrial purposes makes halogenated organic pollutants (HOPs) a global challenge for environmental quality. Current wastewater treatment plants (WWTPs) are successful at reducing chemical oxygen demand (COD), but the removal of HOPs often is poor. Since HOPs are xenobiotics, the biodegradation of HOPs is usually limited in the WWTPs. The current methods for HOPs treatments (e.g., chemical, photochemical, electrochemical, and biological methods) do have their limitations for practical applications. Therefore, a combination of catalytic and biological treatment methods may overcome the challenges of HOPs removal.This dissertation investigated a novel catalytic and biological synergistic platform to treat HOPs. 4-chlorophenol (4-CP) and halogenated herbicides were used as model pollutants for the HOPs removal tests. The biological part of experiments documented successful co-oxidation of HOPs and analog non-halogenated organic pollutants (OPs) (as the primary substrates) in the continuous operation of O2-based membrane biofilm reactor (O2-MBfR). In the first stage of the synergistic platform, HOPs were reductively dehalogenated to less toxic and more biodegradable OPs during continuous operation of a H2-based membrane catalytic-film reactor (H2-MCfR). The synergistic platform experiments demonstrated that OPs generated in the H2-MCfR were used as the primary substrates to support the co-oxidation of HOPs in the subsequent O2-MBfR. Once at least 90% conversation of HOPs to OPs was achieved in the H2-MCfR, the products (OPs to HOPs mole ratio >9) in the effluent could be completely mineralized through co-oxidation in O2-MBfR. By using H2 gas as the primary substrate, instead adding the analog OP, the synergistic platform greatly reduced chemical costs and carbon-dioxide emissions during HOPs co-oxidation.

Methane (CH4) is a prominent greenhouse gas that contributes to the negative impacts of global warming and climate change, whose emissions have more than doubled since the Industrial Revolution primarily due to anthropogenic sources. The main pathways in which methane moves through the environment are methanogenesis and methanotrophy. Methane is primarily generated by acetoclastic methanogenesis in wetlands while it can be oxidized both aerobically and anaerobically. Wetlands are important methane emission sources at 177 - 284 Tg CH4 year-1. The Tres Rios Wetland (TRW) is a constructed facility to complete nutrient removal of treated municipal wastewater, and has shown low emissions of methane. Whether such low emissions could be achieved through active anaerobic oxidation of methane (AOM) is not known, and the main objective of this work is to evaluate the rates of AOM in TRW. In this study an isotopic method and a mass balance method were utilized to determine the rate of AOM from top sediments found at Tres Rios at various locations and in two sets of sampling. The results showed that evidence of AOM occurred in the sediments of both sampling events conducted. The first sampling set showed evidence of AOM at all locations along a transect, showing that oxidation of methane is indeed occurring in Tres Rios sediments. Evidence from both methodologies suggested that high methanogenesis rates occurred at the outside location closest to the water. The second sampling set showed that the highest rate of AOM occurred at the outlet location, with the lowest rate occurring in the middle location. DNA extractions and PCR images resulted in a poor DNA yield, and inability to extract DNA. It was determined that the isotopic approach was less accurate than the mass balance approach due to unexpected delta CH4 values. It was determined that dilutions of CH4 ppm lead to less accurate isotopic measurements needed to estimate AOM rates using a 13C pulse technique. Literature review suggests that factors including water presence, temperature, redox potential, and plant presence can be influential in the oxidation of methane. This AOM assay can be beneficial in better understanding how methane cycles at Tres Rios, and can provide opportunities for future research in determining which factors influence the oxidation of methane in different locations throughout wetlands.

Cyanobacteria and microalgae help reduce the environmental impact of human energy consumption by playing a vital role in carbon and nitrogen cycling. They are also used in various applications like biofuel production, food, medicine, and bioremediation. Understanding how these organisms respond to stress is important for efficient recovery strategies and sustainable outcomes. This study investigated the effects of low-level bleaching and thermal stress on cyanobacteria and microalgae, specifically Synechocystis, Chlorella, and Scenedesmus. The role of ferroptosis, an iron-dependent form of cell death, in the degradation of cellular components under these stressors was examined. Flow cytometry and spectrophotometry were used to measure changes in cellular health and viability. The results showed that temperature influences the type of cell death mechanism and can impact photosynthetic organisms. When treated with Liproxstatin-1, an inhibitor of ferroptosis, both Synechocystis and Chlorella experienced a decrease in oxidative damage, suggesting a potential protective role for the compound. Further investigation into ferroptosis and other forms of cell death, as well as identifying additional inhibitory molecules, could lead to strategies for mitigating oxidative stress and enhancing the resilience of cyanobacteria and microalgae.