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61,005 resultsShowing papers similar to Effects of Ozonation and Anaerobic Digestion on the Physicochemical Properties of Low-Density Polyethylene, Polypropylene, and Polyamide 66 Microplastics
ClearChanges in physical and chemical properties of microplastics by ozonation
Researchers examined how ozone treatment in water systems changes the physical and chemical properties of six common types of microplastics. They found that ozonation altered surface roughness, wettability, and chemical composition of the plastics, with some types being more affected than others. The findings are important because these changes could influence how microplastics interact with other pollutants and organisms in treated water.
Reactivity of four model microplastics with ozone.
Researchers investigated the reactivity of four model microplastic types with ozone, examining how ozone treatment affects the physicochemical properties of microplastics as a potential water treatment strategy for degrading plastic particles.
Ozone-mediated breakdown of microplastics in aqueous environments
Researchers examined how ozone-based advanced oxidation processes break down microplastics in water treatment settings. They found that while ozone can degrade certain plastics, the effectiveness varies depending on particle size, polymer type, and treatment conditions, and the process may generate nanoplastic byproducts. The study highlights both the promise and limitations of ozone treatment as a strategy for removing microplastics from wastewater.
The Potential of Ozonation to Reduce Impact of Waste Sludge-Entrapped Microplastics to Biogas Production
Wastewater treatment plants concentrate microplastics from sewage into the resulting sludge, and this study tested whether ozonation could reduce the harm those microplastics cause during anaerobic digestion used to produce biogas. The findings showed that PET and polypropylene microplastics alter methane yields from sludge digestion in concentration-dependent ways, and that ozone pretreatment partially mitigates the inhibition caused by polypropylene — though the interactions are complex and require further optimization before widespread use.
The effect of Ozonation on the chemical structure of microplastics
Ozone treatment of microplastics in water caused oxidative changes to polymer surfaces including carbonyl group formation and surface cracking, which altered hydrophobicity and potentially increased the capacity of treated particles to adsorb contaminants, suggesting that ozonation in water treatment may chemically transform rather than eliminate microplastic hazards.
The effect of water ozonation in the presence of microplastics on water quality and microplastics degradation
Researchers tested how ozone-based water treatment affects microplastic particles and found that the process can break down the plastics, releasing harmful chemicals like phthalic acid esters into the treated water. Polyethylene was the most susceptible to degradation, with surface area losses up to about 27%. The study suggests that water treatment plants may unintentionally worsen water quality when microplastics are present during ozonation.
Ozonation and its Application in Wastewater Treatment
Not relevant to microplastics — this review covers ozonation and catalytic ozonation as wastewater disinfection and organic pollutant degradation technologies, with no focus on microplastic contamination.
Estudo da degradação de microplásticos em água e efluente secundário de estação de tratamento de esgoto por processos baseados em ozônio
This Brazilian study tested ozone-based water treatment processes for degrading polyethylene microplastics in both clean water and secondary wastewater effluent. While ozonation could break down microplastics into smaller fragments and dissolved organic carbon, it did not fully eliminate them, suggesting the need for combined treatment approaches.
The impact of ozonation on PET and PVC microplastics in model urban wastewater
Researchers investigated the effects of 6-hour ozonation treatment on PET and PVC microplastics in model urban wastewater, evaluating ozonation as an advanced oxidation process for microplastic degradation and assessing changes in polymer structure and surface chemistry for both plastic types.
Effect of ozonation on the morphological characteristics and adsorption behavior of polystyrene microplastics in aqueous environments
Researchers exposed polystyrene microplastics to ozone treatment and found that the aging process made the particles smaller, more negatively charged, and better at absorbing pollutants from water — meaning weathered microplastics in the environment may carry more harmful chemicals than fresh ones.
Effective Removal of Microplastics Using a Process of Ozonation Followed by Flocculation with Aluminum Sulfate and Polyacrylamide
Researchers tested a two-step water treatment process combining ozonation with flocculation to remove microplastics. They found that ozone pretreatment roughened the microplastic surfaces and added chemical groups that dramatically improved removal rates, from 40% to 91%, during the subsequent flocculation step. The findings suggest this combined approach could significantly enhance microplastic removal in conventional water treatment plants.
Transformation of Traditional Wastewater Treatment Methods into Advanced Oxidation Processes and the Role of Ozonation
This paper is not relevant to microplastics research — it reviews advanced oxidation processes with a focus on ozonation for wastewater treatment, covering microbial inactivation and degradation of organic pollutants.
Physicochemical changes in microplastics and formation of DBPs under ozonation
Researchers examined physicochemical changes in thermoplastic polyurethane and polyethylene microplastics during ozonation water treatment, finding that the process can alter microplastic morphology and potentially generate disinfection byproducts.
Aging and Transformation of Polyethylene Microplasticsin UASB Effluents Treated with O3 and O3/H2O2: Physicochemical Changes and Toxicity Assessment
Researchers treated polyethylene microplastics in UASB wastewater reactor effluents with ozone and ozone/hydrogen peroxide, finding that both processes caused significant surface degradation and chemical transformation without increasing toxicity, suggesting safe application for wastewater treatment.
Reactivity of selected model microplastics with ozone
Researchers conducted the first laboratory study on the reactivity of model microplastics — PEEK, PTFE, LDPE, and PET — with atmospheric ozone, finding that ozone alters the surface chemistry of these plastics in ways that could affect their environmental fate and potential to carry other pollutants.
Comparison of surficial modification of micro-sized polyethylenein between by UV/O3 and UVO submerged system
Researchers compared ozone and UV oxidation methods for chemically modifying the surface of polyethylene microplastics in water, finding that different treatment combinations create distinct surface changes. Understanding how weathering alters microplastic surfaces is important for predicting their environmental behavior and toxicity.
Effects of different oxidants on the behaviour of microplastic hetero-aggregates
Researchers studied how different oxidants (ozone, chlorine, UV) affect the aggregation and settling behavior of microplastics in water treatment, finding that oxidation altered surface chemistry and changed hetero-aggregate formation with natural particles. The results have implications for predicting microplastic removal efficiency in drinking water and wastewater treatment plants.
Ozonation facilitates the aging and mineralization of polyethylene microplastics from water: Behavior, mechanisms, and pathways
Ozonation was shown to accelerate the aging and partial mineralization of polyethylene microplastics, with surface oxidation creating more reactive particles susceptible to further degradation. The study provides mechanistic insight into how advanced oxidation processes could contribute to microplastic breakdown in water treatment.
Surface modification of polyethylene microplastic particles during the aqueous-phase ozonation process
Researchers examined the surface modification of polyethylene microplastics during aqueous-phase ozonation, finding that increasing ozone dosage and exposure time progressively increased carbonyl and hydroxyl functional groups on the particle surface. FTIR and XPS analysis showed ozonation altered the surface chemistry of polyethylene microplastics in ways that could change their environmental fate and pollutant adsorption capacity.
Research advances of biodegradable microplastics in wastewater treatment plant: Current knowledge and future directions
This review examines how biodegradable plastics break down into microplastics during wastewater treatment and their effects on the treatment process. Biodegradable microplastics can alter microbial communities in treatment systems and carry pollutants on their surfaces due to abundant oxygen-containing chemical groups. The findings challenge the notion that biodegradable plastics are a complete solution to plastic pollution, since they still generate microplastics that could affect water quality and human health.
Microfibres versus fragments: differential impacts of polyethylene terephthalate (PET) and polyamide (PA6) microplastics on anaerobic digestion efficiency and microbial ecology
Scientists tested how tiny plastic particles affect the breakdown of waste in treatment plants that clean our water. They found that fiber-shaped microplastics (like from synthetic clothing) reduced the system's ability to process waste by up to 17%, while plastic fragments actually helped it work better. This matters because if our wastewater treatment plants become less efficient due to microplastic pollution, it could affect water quality and the environment around us.
Removal of Microplastics By Ozone Oxidation from Urban Wastewater Using Taguchi Experimental Design
Researchers evaluated ozone oxidation as a method for removing microplastics from urban wastewater treatment plant effluent, using Taguchi experimental design to optimize the process. The study identified optimal conditions of pH 7 with specific ozone doses and reaction times for effective microplastic removal, demonstrating that ozone treatment could be a viable approach for reducing microplastic discharge from wastewater facilities.
Effect of Microplastics on Anaerobic Digestion Process with Rapidly Degradable Organic Matter
Scientists tested how tiny plastic particles affect the process that breaks down waste to produce energy at treatment plants. They found that these microplastics can reduce the amount of useful gas produced by up to 24%, with some types of plastic causing more problems than others. This matters because it could make our waste treatment systems less efficient, potentially affecting how well we clean our water and manage waste that could impact our environment and health.
Tertiary/quaternary treatment of urban wastewater by UV/H2O2 or ozonation: Microplastics may affect removal of E. coli and contaminants of emerging concern
Researchers investigated how polyethylene microplastics interfere with UV/hydrogen peroxide and ozonation treatments used to disinfect urban wastewater. They found that increasing microplastic concentrations reduced the effectiveness of both treatment methods at killing E. coli bacteria and degrading pharmaceutical contaminants. The study suggests that microplastic pollution in wastewater could compromise advanced treatment processes designed to protect public health.