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Papers
61,005 resultsShowing papers similar to Norfloxacin removal efficiency by a carbon filtration column under the influence of nanoplastics: mechanistic analysis and prediction model
ClearTransport behavior of nanoplastics in activated carbon column
Researchers investigated the transport and retention of nanoplastics through granular activated carbon columns used in drinking water treatment. Nanoplastics were partially retained in activated carbon but their behavior depended on particle surface charge and solution chemistry, with implications for drinking water safety.
Remoção de antibióticos da água por nanofiltração
This paper is not about microplastics. It evaluates nanofiltration membrane technology for removing antibiotics (tetracycline, norfloxacin, and sulfamethoxazole) from water, achieving up to 95% removal. While water treatment technology is broadly relevant to contaminant removal, this study focuses specifically on pharmaceutical contamination rather than microplastic pollution or exposure.
Nanoplastics removal during drinking water treatment: Laboratory- and pilot-scale experiments and modeling
Researchers used palladium-labeled nanoplastics to track removal through conventional drinking water treatment including ozonation and filtration, finding that biofilm-coated aged sand provided the best nanoplastic retention. Modeling predicted that a combination of three consecutive filtration steps could achieve removal exceeding 3-log units, with slow sand filtration contributing the most to overall nanoplastic removal.
Advanced Carbon Nanoparticle-Based Filtration Systems for Water Disinfection and Microplastics Removal
This study proposes a carbon nanoparticle-infused membrane filter (NP-WFS) as a combined solution for removing both microplastics and microbial contaminants from drinking water. Laboratory tests showed the membrane captured microplastic particles and microorganisms, suggesting that nanoparticle-based filtration could offer a practical improvement over conventional water treatment where microplastics currently pass through.
Tracking microplastics in a drinking water supply system proximity to industrial facilities: Occurrence, source identification, and risk assessment
Researchers comprehensively investigated microplastic occurrence, sources, and health risks in a drinking water supply system near industrial facilities, finding that a granular activated carbon filter removed 93.39% of microplastics at the treatment plant. However, microplastic abundance increased during distribution, highlighting post-treatment contamination as a critical but underappreciated exposure pathway.
Fate and removal efficiency of polystyrene nanoplastics in a pilot drinking water treatment plant
Researchers investigated how effectively a pilot-scale drinking water treatment plant removes polystyrene nanoplastics. The study found that sand and activated carbon filtration alone achieved 88.1% removal, but adding a coagulation step dramatically improved removal efficiency to 99.4%, with most nanoplastics captured during the sand filtration process.
Norfloxacin removal by ultraviolet-activated sodium percarbonate and sodium hypochlorite: process optimization and anion effect
This paper is not about microplastics; it evaluates UV-activated chemical processes for removing the antibiotic norfloxacin from water.
Removal of nanoparticles (both inorganic nanoparticles and nanoplastics) in drinking water treatment – coagulation/flocculation/sedimentation, and sand/granular activated carbon filtration
Researchers reviewed the removal of inorganic nanoparticles and nanoplastics during conventional drinking water treatment, finding that coagulation/flocculation/sedimentation and sand/granular activated carbon filtration can substantially reduce nanoparticle concentrations but with variable efficiency depending on particle type.
Characterization of microplastics and their interaction with antibiotics in wastewater
Researchers characterized microplastics in wastewater and investigated their interactions with antibiotics, examining how microplastic surfaces adsorb antibiotic compounds and the implications for antibiotic transport and dissemination in wastewater treatment systems.
The impact of chlorination on the tetracycline sorption behavior of microplastics in aqueous solution
Researchers found that chlorination, a common disinfection step in wastewater treatment, alters the surface chemistry of microplastics and changes their capacity to adsorb tetracycline antibiotics, with chlorinated microplastics showing modified sorption behavior that affects their role as antibiotic carriers.
Paving roads with recycled plastics: Microplastic pollution or eco-friendly solution?
This study assessed the capability of granular activated carbon filtration to remove nanoplastics from drinking water, finding approximately 85% removal efficiency for particles below 1 micrometer. Removal was lower for smaller, hydrophilic particles that resist adsorption.
Removal of microplastics and nanoplastics in water treatment processes: A systematic literature review
Researchers systematically reviewed 103 studies across 26 water treatment plants in 12 countries to assess how well various technologies remove microplastics and nanoplastics from drinking water, finding that while coagulation, filtration, and advanced treatments help, significant gaps remain. The review identifies that no single process achieves complete removal, leaving microplastics as a persistent contaminant in treated water supplies.
Removal of sulfamethoxazole using Fe-Mn biochar filtration columns: Influence of co-existing polystyrene microplastics
Researchers investigated how polystyrene microplastics affect the removal of the antibiotic sulfamethoxazole using iron-manganese modified biochar filtration columns. They found that the presence of microplastics significantly reduced antibiotic retention due to competitive sorption, with the effect varying depending on water pH. The study highlights that co-occurring microplastics in wastewater can interfere with contaminant removal systems, potentially allowing more antibiotics to pass through treatment processes.
(Micro) nanoplastics promote the risk of antibiotic resistance gene propagation in biological phosphorus removal system
The presence of microplastics and nanoplastics in a biological phosphorus removal system used in wastewater treatment promoted the dissemination of antibiotic resistance genes, while also disrupting phosphorus removal efficiency. The study links micro- and nanoplastic contamination of treatment systems to both reduced process performance and increased antimicrobial resistance risk.
Fate of microplastics in the drinking water production
Researchers tracked the fate of microplastics through drinking water treatment processes, finding that conventional treatment steps like coagulation, sedimentation, and filtration removed the majority of microplastics but did not eliminate them entirely.
Evaluating theEfficiency of Enhanced Coagulationfor Nanoplastics Removal Using Flow Cytometry
Researchers evaluated the efficiency of enhanced coagulation for removing nanoplastics from water using flow cytometry as a quantification tool, addressing the interconnected challenges of nanoplastic removal and detection in conventional water treatment systems.
Understanding and Improving Microplastic Removal during Water Treatment: Impact of Coagulation and Flocculation
Researchers systematically tested coagulation and flocculation for removing microplastics from drinking water, finding that removal efficiency depended strongly on plastic particle size and whether particles had been weathered, with smaller pristine particles being the hardest to remove.
Understanding and characteristics of coagulation removal of composite pollution of microplastic and norfloxacin during water treatment
The coagulation removal of microplastics and the antibiotic norfloxacin together was studied in a water treatment context, finding that the presence of microplastics altered the coagulation behavior of norfloxacin and that their combined removal was less effective than treating either pollutant alone. The results highlight composite pollution as a challenge for conventional water treatment processes.
Occurrence and removal of microplastics by advanced and conventional drinking water treatment facilities
Researchers assessed microplastic occurrence and removal efficiency at drinking water treatment plants using both conventional and advanced treatment processes. Advanced treatment steps such as ultrafiltration and activated carbon significantly improved microplastic removal compared to conventional coagulation and filtration alone.
Fe-Modified Sewage Sludge Biochar for Efficient Removal of Nanoplastics from Water: Mechanistic Insights and Multi-Pathway Adsorption Analysis
Scientists developed a new water filter material made from sewage sludge and iron that can remove 96% of tiny plastic particles (called nanoplastics) from water. These microscopic plastic bits are found everywhere in our water supply and may pose health risks, but this new filter works much better than existing methods. This research could lead to better ways to clean nanoplastics from our drinking water while also recycling waste materials.
Mechanistic insight into different adsorption of norfloxacin on microplastics in simulated natural water and real surface water
This study compared the adsorption of norfloxacin antibiotic onto microplastics in simulated natural water versus real surface water, finding that natural organic matter and competing ions in real water significantly reduced antibiotic uptake by microplastics.
Carbon nanomaterials for co-removal of antibiotics and heavy metals from water systems: An overview
This review examines how carbon-based nanomaterials can simultaneously remove antibiotics and heavy metals from contaminated water. While the focus is on water treatment rather than human health directly, the study notes that microplastics in the environment can affect how well these cleanup methods work. The authors highlight that these advanced materials show strong potential but need further evaluation of their cost-effectiveness for real-world use.
Removal efficiency of micro- and nanoplastics (180 nm–125 μm) during drinking water treatment
Researchers tested how effectively standard drinking water treatment processes remove micro- and nanoplastics ranging from 180 nanometers to 125 micrometers. They found that coagulation and sedimentation alone removed less than 2% of plastic particles, while granular filtration was far more effective, achieving 87% to nearly 100% removal depending on particle size. The study also found that biofilm formation on microplastics significantly improved their removal during coagulation treatment.
Recent advances on micro/nanoplastic pollution and membrane fouling during water treatment: A review
Researchers reviewed recent advances in understanding how micro- and nanoplastics contribute to membrane fouling during water treatment processes. The study found that while membrane separation effectively removes microplastics from wastewater effluent, fouling caused by plastic particles along with dissolved organics and extracellular polymers remains a key obstacle, and understanding the fouling mechanisms is critical for improving treatment efficiency.