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1. Wetland Removal Mechanisms for Emerging Contaminants

   https://doi.org/10.3390/land12020472  

   Overton, Olivia Celeste; Olson, Leif Hans; Majumder, Sreemala Das; Shwiyyat, Hani; Foltz, Mary Elizabeth; Nairn, Robert William (February 2023, Land)

   In recent decades, previously unobserved trace compounds have become more widely detected in wastewater treatment effluents and freshwater ecosystems. Emanating from various sources and presenting potential human health and ecological risks at much lesser concentrations than traditional contaminants, detection of “emerging contaminants” has increased with improvements in analytical techniques. The behavior of emerging contaminants in wetlands is a topic of increasing interest, as natural wetlands are known to transform and sequester pollutants and constructed or treatment wetlands are widely utilized to address elevated concentrations of constituents of concern. Both natural and constructed wetlands are complex biogeochemical systems with interrelated abiotic and biotic mechanisms leading to the removal of emerging contaminants. A literature review was performed to assess the current state of knowledge of various wetland mechanisms involved in removing these contaminants from surface waters and effluents. The primary mechanisms discussed in the literature are sorption, photodegradation, microbial biodegradation and phytoremediation. The most influential mechanisms are dependent on the properties of the contaminants and wetland systems studied. Common trends exist for different constructed wetland designs to leverage various mechanisms based on hydrology, substrate and vegetation plantings. Much remains to be understood about the various processes occurring in wetlands as they relate to emerging contaminant removal. Improving the understanding of the potential role of wetland mechanisms can help manage this environmental challenge more effectively. 

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2. Nutrient Removal Rates of Permeable Reactive Concrete

   https://doi.org/https://doi.org/10.1061/JSWBAY.0000850  

   Ramsey, Andrew J.; Hart, Megan L.; Kevern, John T. (February 2018, Journal of sustainable water in the built environment)

   Nitrogen and phosphorus contained in stormwater runoff contaminate both surface and groundwaters, causing problems for natural aquatic systems and human health. Pervious concrete specifically designed for pollutant removal, otherwise known as permeable reactive concrete (PRC), may be used as a novel component of existing infrastructure to remove nutrients from runoff. This research compares the removal and retention of dissolved, inorganic nitrate-nitrogen (NO3-N) and orthophosphate-phosphorus (PO4-P) for three PRC mixtures. The control PRC was ordinary portland cement (OPC) and was compared against other mixtures containing 25% replacement with Class C fly ash or with drinking water treatment residual waste (DWTR). Concrete specimens were jar-tested for 72 h in three different concentrations of nitrate or phosphate. The control mixture removed 60% of NO3-N and more than 80% PO4-P, and the fly ash mixture removed up to 39% of NO3-N and more than 91% PO4-P. The DWTR mixture leached NO3-N while removing more than 80% PO4-P. Linear isotherms were determined for the range of nutrient concentrations tested. Column leach tests were conducted on specimens after initial jar testing and used as an indication of removal permanence. Inorganic removal mechanisms were investigated, including crystallographic substitution, adsorption, and physical solute filtering in cement pore space. Results indicate PRC can be one of the leading methods to remove nitrate from surface waters and is as efficient as other methods for orthophosphate removal. 

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3. Nutrient retention via sedimentation in a created urban stormwater treatment wetland.

   Griffiths, L.N.; W.J. Mitsch, W.J. (April 2020, Science of the total environment)

   Nutrient removal by a 4.6-ha urban stormwater treatment wetland system in a 20-ha water/nature park in southwest Florida has been investigated for several years, suggesting that the wetlands are significant sinks of both phosphorus and nitrogen although with a slightly decreased total phosphorus retention in recent years. This study investigates the role of sedimentation on changes in nutrient concentrations and fluxes through these wetlands. Sedimentation bottles along with sediment nutrient analyses every six months allowed us to estimate gross sedimentation rates of 9.9±0.1 cm yr−1 and nutrient sedimentation rates of approximately 7.8 g-P m−2 yr−1 and 81.7 g-Nm−2 yr−1. Using a horizon marker method to account for lack of resuspension in the sedimentation bottles suggested that net nutrient retention by sedimentation may be closer to 1.5 g-Pm−2 yr−1 and 33.2 g-N m−2 yr−1. Annual nutrient retention of the wetland system determined from water quality measurements at the inflow and outflow averaged 4.23 g-P m−2 yr−1 and 11.91 g-N m–2 yr−1, suggesting that sedimentationis a significant pathway for nutrient retention in these urban wetlands and that resuspension is playing a significant role in reintroducing nutrients, especially phosphorus, to the water column. These results also suggest that additional sources of nitrogen not in our current nutrient budgets may be affecting overall nutrient retention. 

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4. Disconnectivity matters: the outsized role of small ephemeral wetlands in landscape-scale nutrient retention

   https://doi.org/10.1088/1748-9326/acab17  

   Cheng, Frederick Y.; Park, Junehyeong; Kumar, Mukesh; Basu, Nandita B. (January 2023, Environmental Research Letters)

   Abstract Wetlands protect downstream waters by filtering excess nitrogen (N) generated from agricultural and urban activities. Many small ephemeral wetlands, also known as geographically isolated wetlands (GIWs), are hotspots of N retention but have received fewer legal protections due to their apparent isolation from jurisdictional waters. Here, we hypothesize that the isolation of the GIWs make them more efficient N filters, especially when considering transient hydrologic dynamics. We use a reduced complexity model with 30 years of remotely sensed monthly wetland inundation levels in 3700 GIWs across eight wetlandscapes in the US to show how consideration of transient hydrologic dynamics can increase N retention estimates by up to 130%, with greater retention magnification for the smaller wetlands. This effect is more pronounced in semi-arid systems such as the prairies in North Dakota, where transient assumptions lead to 1.8 times more retention, compared to humid landscapes like the North Carolina Pocosins where transient assumptions only lead to 1.4 times more retention. Our results highlight how GIWs have an outsized role in retaining nutrients, and this service is enhanced due to their hydrologic disconnectivity which must be protected to maintain the integrity of downstream waters. 

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5. Emerging investigator series: 3D printed graphene-biopolymer aerogels for water contaminant removal: a proof of concept

   https://doi.org/10.1039/D0EN00953A  

   Masud, Arvid; Zhou, Chi; Aich, Nirupam (January 2021, Environmental Science: Nano)

   null (Ed.)

   Graphene-based 3D macroscopic aerogels with their hierarchical porous structures and mechanical strength have been widely explored for removing contaminants from water. However, their large-scale manufacturing and application in various water treatment processes are limited by their scalability. In this study, we report a proof-of-concept direct ink writing (DIW) 3D printing technique and subsequent freeze-drying to prepare graphene-biopolymer aerogels for water treatment. To provide appropriate rheology for DIW printability, two bio-inspired polymers, polydopamine (PDA) and bovine serum albumin (BSA), were added to the graphene-based ink. The biopolymers also contributed to the contaminant removal capacity of the resultant graphene-polydopamine-bovine serum albumin (G-PDA-BSA) aerogel. The physicochemical properties of the aerogel were thoroughly characterized from the nano- to macroscale. The 3D printed aerogel exhibited excellent water contaminant removal performance for heavy metals (Cr( vi ), Pb( ii )), organic dyes (cationic methylene blue and anionic Evans blue), and organic solvents ( n -hexane, n -heptane, and toluene) in batch adsorption studies. The electrostatic interaction dominated the removal of heavy metals and dyes while the hydrophobic interaction dominated the removal of organic solvents from water. Moreover, the aerogel showed superb regeneration and reuse potential. The aerogel removed 100% organic solvents over 10 cycles of regeneration and reuse; additionally, the removal efficiencies for methylene blue decreased by 2–20% after the third cycle. The fit-for-design 3D printed aerogel was also effectively used as a bottle-cap flow-through filter for dye removal. The potential and vision of the 3D printing approach for graphene-based water treatment presented here can be extended to other functional nanomaterials, can enable shape-specific applications of fit-for-purpose adsorbents/reactors and point-of-use filters, and can materialize the large-scale manufacturing of nano-enabled water treatment devices and technologies. 

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