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1. Longevity of Bioretention Depths for Preventing Acute Toxicity from Urban Stormwater Runoff

   Maguire, L.M. (August 2024, EWRI Low Impact Development Congress)

   Urbanization poses increasing threats to aquatic ecosystems, including increased chemical loading. Of relatively recent concern is the potential of urban stormwater runoff to facilitate the spread of microplastics (MPs), including tire wear particles. Previous studies have demonstrated the effectiveness of bioretention treatment systems in treating runoff, thereby reducing chemical loading into surface waters and preventing acutely lethal and sublethal effects to aquatic organisms. In this study, we aimed to determine the effectiveness and longevity of bioretention soil media (BSM) at various infiltration depths, including the shallower depth currently required by the Washington Department of Ecology (18”). Experimental columns containing three different BSM depths were dosed with roadway runoff at an accelerated rate to simulate nine water years in approximately 30 calendar months. The chemical and biological effectiveness of the columns in treating runoff was assessed by analyzing influent/effluent chemistry and characterizing the health of juvenile coho salmon (Oncorhynchus kisutch). Bioretention treatment efficiently removed copper, zinc, total PAHs, and total suspended solids (> 70% removal). Influent stormwater runoff was acutely lethal to juvenile coho salmon (88, 90, 100, and 56.3% mortality in four exposures across the nine accelerated years). However, bioretention treatment was protective of coho, altogether preventing mortality for all treatment depths in three exposures and all but one depth in the last exposure, likely due to overflow when influent flow exceeded the ponding capacity of some of the columns. This study is ongoing and will continue to assess bioretention effectiveness through 10 accelerated years. Future research should consider the ability of bioretention systems to remove MPs and associated pollutants in runoff and explore the fate of MP-contaminant complexes in bioretention systems. Although contaminants themselves, MPs can also act as vectors of other contaminants of concern in aquatic ecosystems, including antibiotic resistance genes (ARGs). Contaminants co-occurring in runoff (e.g., heavy metals) can stimulate the selection or amplification of these ARGs. If left untreated, runoff carrying ARGs to surface waters could increase resistance in environmental bacteria and risks to human health. 

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2. Field Evaluation of Rice Husk Biochar and Pine Tree Woodchips for Removal of Tire Wear Particles from Urban Stormwater Runoff in Oxford, Mississippi (USA)

   https://doi.org/10.3390/su17094080  

   Olubusoye, Boluwatife S; Cizdziel, James V; Wontor, Kendall; Li, Ruojia; Hambuchen, Rachel; Aminone, Voke Tonia; Moore, Matthew T; Bennett, Erin R (May 2025, Sustainability)

   Tire wear particles (TWPs), a form of microplastics (MPs) pollution, are transported into waterbodies through stormwater runoff, leading to environmental pollution and impacts on associated biota. Here, we investigated the effectiveness of stormwater filter socks filled with rice husk biochar or pine tree woodchips in reducing TWP pollution in urban runoff in Oxford, Mississippi. Triplicate runoff samples were collected upstream and downstream of the biofilters at two sites during two storm events at peak flow within minutes of the start of the storm and after 30 min. Samples were analyzed for TWPs using a combination of stereomicroscopy, micro-attenuated total reflectance Fourier transform infrared spectroscopy (µ-ATR-FTIR), and scanning electron microscopy (SEM) with energy dispersive X-ray spectroscopy (EDX). Concentrations (TWPs/L) upstream of the biofilter were variable but highest at the start of the runoff, dropping from an average of 2811 ± 1700 to 476 ± 63 after 30 min at site 1 and from 2702 ± 353 to 2356 ± 884 at site 2. Biochar was more effective than woodchips (p < 0.05) at removing TWPs, reducing concentrations by an average of 97.6% (first use) and 85.3% (second use) compared to 66.2% and 54.2% for woodchips, respectively. Biochar was particularly effective at removing smaller TWPs (<100 µm). Both materials became less effective with use, suggesting fewer available trapping sites and the need for removal and replacement of the material with time. Overall, this study suggests that biochar and woodchips, alone or in combination, deserve further scrutiny as a potential cost-effective and sustainable method to mitigate the transfer of TWPs to aquatic ecosystems and associated biota. 

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3. Treatment of Dairy Farm Runoff in Vegetated Bioretention Systems Amended with Biochar

   https://doi.org/10.3390/w16101347  

   Rahman, Md_Yeasir A; Richardson, Nicholas; Nachabe, Mahmood H; Ergas, Sarina J (May 2024, Water)

   Nitrogen and fecal indicator bacteria (FIB) in runoff from concentrated animal feeding operations (CAFOs) can impair surface and groundwater quality. Bioretention systems are low impact nature-based technologies that can effectively treat CAFO runoff if modified with an internal water storage zone (IWSZ) or amended with biochar. In this study, the performances of four pilot-scale modified bioretention systems were compared to assess the impacts of (1) amending bioretention media with biochar and (2) planting the systems with Muhlenbergia. The system with both plants and biochar amendment had the best performance, with an average of 5.58 log reduction in E. coli and 98% removal of total nitrogen (TN). All systems treated the first pore volume well as new runoff flushed the treated water from the IWSZ. Biochar improved TN and FIB removal due to its high capacity to adsorb or retain ammonium (NH4+), dissolved organic nitrogen, dissolved organic carbon, and E. coli. Planting improved performance, possibly by increasing rhizosphere microbial activity. 

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4. Performance and Environmental Assessment of Biochar-Based Membranes Synthesized from Traditional and Eco-Friendly Solvents

   https://doi.org/10.3390/membranes14070153  

   Fionah, Abelline; Oluk, Isaac; Brady, Laura; Byrne, Diana M; Escobar, Isabel C (July 2024, Membranes)

   Water contamination resulting from coal spills is one of the largest environmental problems affecting communities in the Appalachia Region of the United States. This coal slurry contains potentially toxic substances, such as hydrocarbons, heavy metals, and coal cleaning chemicals, and its leakage into water bodies (lakes, rivers, and aquifers) can lead to adverse health effects not only for freshwater bodies and plant life but also for humans. This study focused on two major experiments. The first experiment involved the use of biochar to create a biochar–polysulfone (BC-PSf) flat-sheet multifunctional membrane to remove organic contaminants, and the other major experiment compared eco-friendly (gamma-valerolactone—GVL; Rhodiasolv® PolarClean—PC) and petroleum-derived solvents (i.e., N-methyl-pyrrolidone—NMP) in the fabrication of the biochar–polysulfone membranes. The resulting membranes were tested for their efficiency in removing both positively and negatively charged organic contaminants from the collected water at varying pH values. A comparative life cycle assessment (LCA) with accompanying uncertainty and sensitivity analyses was carried out to understand the global environmental impacts of incorporating biochar, NMP, GVL, and PC in the synthesis of PSf/NMP, BC-PSf/NMP, PSf/GVL, BC-PSf/GVL, PSf/PC, and BC-PSf/PC membranes at a set surface area of 1000 m2. The results showed that the addition of biochar to the membrane matrix increased the surface area of the membranes and improved both their adsorptive and mechanical properties. The membranes with biochar incorporated in their matrix showed a higher potential for contaminant removal than those without biochar. The environmental impacts normalized to the BC-PSf/GVL membrane showed that the addition of biochar increased global warming impacts, eutrophication, and respiratory impacts by over 100% in all the membrane configurations with biochar. The environmental impacts were highly sensitive to biochar addition (Spearman’s coefficient > 0.8). The BC/PSf membrane with Rhodiasolv® PolarClean had the lowest associated global environmental impacts among all the membranes with biochar. Ultimately, this study highlighted potential tradeoffs between functional performance and global environmental impacts regarding choices for membrane fabrication. 

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5. Development of crosslinked polyvinyl alcohol nanofibrous membrane for microplastic removal from water

   https://doi.org/10.1002/app.55428  

   Gopakumar, Anandu_Nair; Ccanccapa‐Cartagena, Alexander; Bell, Kati; Salehi, Maryam (March 2024, Journal of Applied Polymer Science)

   Abstract This study presents the development of an innovative nanofibrous membrane to remove microplastics (MPs) from drinking water. This membrane exhibits additional functionality in removing lead (Pb), highlighting its promising potential for utilization as a point‐of‐use (POU) device. The polyvinyl alcohol (PVA) nanofibrous membranes are crosslinked using glutaraldehyde, and their efficiencies in the removal of MPs are evaluated. The results show that crosslinking the 7 and 10 wt% PVA nanofibers increases their average diameters to 330 and 581 nm, respectively, and enhances their surface area. The treatment efficiency of crosslinked PVA fibrous media is evaluated using polyethylene (PE) (5 μm ≤d ≤ 25 μm) and polystyrene (PS) MPs (d ≤ 1 μm). The filtration efficiencies of both 7 and 10 wt% c‐PVA nanofibrous media are found to be 99.8% ± 0.1% in the removal of PE MPs at pH 8. Further examination of the filtration efficiency in the removal of PS MPs shows that the highest removal efficiency achieved was 77.3% ± 1.4% at a pH of 6. Additionally, the lead removal efficiency of this fibrous membrane in flow‐through experiments is examined. Results show a pH‐dependent lead removal efficiency, in which the greatest efficiency of 69% is found at pH 6. 

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