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1. Effects of halide ions on photochemically-induced abiotic formation of Mn oxides

   Gao, Zhenwei ; Skurie, Charlie ; Jun, Young-Shin ( August 2020 , American Chemical Society National Meeting)

   Manganese (Mn) oxides have excellent oxidation and adsorption capabilities that can affect geochemical element cycling and the fate of pollutants in the environment. Naturally existing Mn oxides are believed to be formed mainly by oxidation of Mn2+(aq) mediated by fungi or bacteria, while abiotic Mn oxidation has been considered a minor contribution due to its slow kinetics. However, in a recent study, we discovered abiotic inorganic oxidation of Mn2+(aq) to δ-MnO2 by superoxide radicals generated from nitrate photolysis at a rate comparable to that of biotic processes. In the current study, we investigated the effects of abundant halide ions (such as Cl−) on photochemically-driven oxidation of Mn2+(aq). Halide ions are abundant in the environment and many engineered systems, including seawater and blackish water, as well as effluent water from desalination and unconventional oil and gas recovery. Halide ions can participate in photochemical Mn2+ oxidation reactions by forming additional radicals. We found that in the presence of halide ions, the oxidation rates of Mn2+ and quantities of formed Mn oxides were both increased. In addition, high concentrations of halide ions greatly changed the ionic strengths of the systems, affecting the crystallinity of the resulting Mn oxide. Our findings highlight unexpected impacts of halogen ions on solid formations in surface water rich in halides. 

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2. Effects of reactive halogen species on the formation of photochemically-induced abiotic MnIV oxides

   Gao, Zhenwei ; Skurie, Charlie ; Jun, Young-Shin ( April 2021 , American Chemical Society National Meeting)

   null (Ed.)

   Manganese (Mn) oxides are strongly oxidative and adsorptive, thus affecting natural geochemical cycling and the fate and transport of pollutants. Because abiotic Mn oxidation kinetics are known to be slow, MnIV oxides have been assumed to be formed by fast oxidation of Mn2+(aq), mediated by fungi or bacteria. Recently, our group discovered that superoxide radicals generated from nitrate photolysis, a simple reaction of nitrate ions and sunlight, can facilitate the oxidation of Mn2+(aq) to δ-MnIVO2 at a rate comparable to that of biotic processes. This finding motivated us to explore underappreciated oxidants in the environment. Considering the historically unprecedented large quantity of highly saline brine generated from energy and water production, we examined the effects of halide ions (such as Cl- and Br-) and their reactive radical species on photochemically-driven Mn2+(aq) oxidation and MnIV oxide formation. Halide ions are abundant in highly saline brine such as seawater and brackish water, as well as in effluent water from desalination and unconventional oil and gas recovery. Under circumneutral pH and ambient temperature, we found that the presence of halide ions increases the oxidation rates of Mn2+ and the quantities of formed MnIV oxides within a few hours. Moreover, because high concentrations of halide ions greatly change the ionic strengths of the systems, they affect the crystallinity of the resulting MnIV oxide phases. Our findings highlight the unexpected impacts of halogen ions on solid formations in highly saline brine and emphasize the importance of brine photochemistry. 

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3. Photochemically-induced formation of manganese oxide nanoparticles by reactive halogen radicals in briny water

   Gao, Zhenwei ; Skurie, Charlie ; Liu, Jing ; Jun, Young-Shin ( August 2022 , The 2022 Fall ACS National Meeting & Exposition)

   In meeting rapidly growing demands for energy and clean water, engineered systems such as unconventional oil and gas recovery and desalination processes produce large amounts of briny water. In the environment, these highly concentrated halides can be oxidized and transformed to reactive halogen radicals, whose roles in the degradation and transformation of organic pollutants have been studied. However, redox reactions between halogen radicals and heavy metal ions are still poorly understood. In this work, we found that aqueous manganese ions (Mn2+) could be oxidized to Mn oxide solids by reactive halogen radicals generated from reactions between halide ions and hydroxyl radicals or between halide ions and triplet state dissolved organic matter. In particular, more Mn2+ was oxidized by Br radicals generated from bromide ion (Br−) than by Cl radicals generated from chloride ion (Cl−), even though the concentrations of Br− in surface waters are much lower than Cl− concentrations. In addition, the highly concentrated halides greatly increased the ionic strength of the solution, affecting Mn2+ oxidation kinetics and the crystallinity and oxidation state of the newly formed Mn oxides. These newly discovered pathways involving Mn2+(aq) and reactive halogen radicals aid in understanding the generation of abiotic Mn oxide solids and forecasting their redox activities. Moreover, this work emphasizes the critical need for a better knowledge of the roles of reactive halogen radicals in inorganic redox reactions. 

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4. Photochemically-assisted Formation of Manganese Oxide Solids in the Presence of Dissolved Organic Matter and Bromide Ions

   Gao, Zhenwei ; Liu, Jing ; Skurie, Charlie ; Zhu, Yaguang ; Jun, Young-Shin ( June 2022 , the 2022 Association of Environmental Engineering and Science Professors (AEESP) Research and Education Conference)

   Dissolved natural organic matter (DOM) is a complex matrix of organic matter that is ubiquitous in natural aquatic environments. So far, substantial research has been conducted on the DOM adsorption on Mn oxides as well as the reduction processes of Mn oxides by DOM. However, little is known about the oxidative roles of DOM in oxidizing Mn2+(aq) to Mn(III/IV) oxide solids. Sunlight-driven processes can initiate the degradation of DOM accompanied by the formation of photochemically produced reactive intermediates, including excited triplet state DOM (3DOM*), hydroxyl radical (•OH), superoxide radical (O2•−), hydrogen peroxide (H2O2), and singlet oxygen (1O2). Further, in the presence of halide ions, reactive halogen species can be generated by reactions between 3DOM* and halide ions, and by reactions between •OH and halide ions. In this study, we found that the solution pH controlled the oxidation of Mn2+(aq) to Mn oxide solids during photolysis of DOM. Among the reactive oxygen species, Mn2+(aq) was found to be oxidized to Mn oxide solids mainly by O2•−. The DOM with different quantities of aromatic functional groups affected its oxidative capability. With the addition of bromide ions (Br−), Mn2+(aq) oxidation was promoted further by formation Br radicals, which can also oxidize Mn2+(aq) to Mn oxide solids. These findings can help us better understand the oxidative role of DOM in the formation of Mn oxide solids in organic-rich surface water. In addition, this study assists in comprehending the impacts of the photolytic reactions between DOM and halide ions and their resulting reactive oxygen and halogen species on the oxidation and reduction processes of other transition metal oxides in the environment. 

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5. Abiotic manganese oxidation by peroxyl radicals generated from the reaction between hydroxyl radicals and their alcohol scavengers

   Gao, Zhenwei ; Jun, Young-Shin ( August 2022 , The 2022 Fall ACS National Meeting & Exposition)

   Environmentally ubiquitous manganese (Mn) oxides play important roles in geochemical element redox cycling. They can be formed by both biotic and abiotic Mn2+(aq) oxidation processes. We recently observed photochemically-assisted abiotic oxidation of Mn2+(aq) to δ-MnO2 nanosheets during nitrate photolysis. Mn2+ was mainly oxidized by superoxide radicals, while hydroxyl radicals (•OH) contributed little to Mn oxidation. However, unexpected abiotic Mn2+ oxidation was observed in the presence of tert-butyl alcohol (TBA) that was added to scavenge •OH. TBA, one of the most common •OH scavengers, has been thought to be able to completely scavenge •OH, leaving less reactive products that do not participate in further redox reactions in the system. However, we discovered that TBA was not an inert agent in scavenging •OH. Secondary peroxyl radicals (ROO•) were produced from the chain reactions between TBA and •OH, facilitating the oxidation of Mn2+ to MnO2(s). These findings can also be applied to other alcohol scavengers, such as methanol, ethanol, and propanol. In addition, ROO• can be produced by the reaction between •OH and unsaturated organic matter in natural environments. This study helps understand the occurrences of Mn oxides in the environment, and it provides new insights into the oxidation pathways of other heavy metals ions (Fe2+, As3+, and Cr3+) by ROO•. 

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