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Papers
61,005 resultsShowing papers similar to Acetylation of cotton knitted fabrics for improved quick drying after water absorption
ClearControlled surface acetylation of cellulosics to tune biodegradability while expanding their use towards common petrochemical-based plastics
Not relevant to microplastics — this study demonstrates surface acetylation of cellulose paper fibers to improve wet strength and moisture resistance while maintaining biodegradability, positioned as an alternative to petrochemical plastics.
Acrylic fabrics as a source of microplastics from portable washer and dryer: Impact of washing and drying parameters
Researchers quantified microfiber release from acrylic fabrics during washing and drying in a portable appliance under various conditions, finding that doubling wash or dry time approximately doubled fiber release and that using detergent increased release nearly 3-fold compared to water alone. Fiber release decreased across successive laundering cycles as the fabric shed its most loosely attached fibers early in its use life.
The Effect of the Physical and Chemical Properties of Synthetic Fabrics on the Release of Microplastics during Washing and Drying
Researchers investigated how the physical and chemical properties of synthetic fabrics influence microplastic fiber release during washing and drying, finding that fabric construction, fiber type, and surface treatment are key determinants of the quantity and characteristics of released microplastic particles.
TextileRecycling’s Hidden Problem: Surface-ModifiedFiber Fragments Emitted at Every Stage
Researchers investigated microplastic fiber (MPF) release during chemical recycling of polyester/cotton-blended textiles, finding that the dye removal stage emitted the highest MPF count at nearly 10,055 MPFs per gram, while alkaline hydrolysis reduced MPF release by 87.55% compared to acid hydrolysis during the treatment stage.
TextileRecycling’s Hidden Problem: Surface-ModifiedFiber Fragments Emitted at Every Stage
Researchers investigated microplastic fiber (MPF) release during chemical recycling of polyester/cotton-blended textiles, finding that the dye removal stage emitted the highest MPF count at nearly 10,055 MPFs per gram, while alkaline hydrolysis reduced MPF release by 87.55% compared to acid hydrolysis during the treatment stage.
TextileRecycling’s Hidden Problem: Surface-ModifiedFiber Fragments Emitted at Every Stage
Researchers investigated microplastic fiber (MPF) release during chemical recycling of polyester/cotton-blended textiles, finding that the dye removal stage emitted the highest MPF count at nearly 10,055 MPFs per gram, while alkaline hydrolysis reduced MPF release by 87.55% compared to acid hydrolysis during the treatment stage.
Pectin based finishing to mitigate the impact of microplastics released by polyamide fabrics
Researchers developed a pectin-based finishing treatment for polyamide fabrics that reduced microfibre shedding during washing by approximately 90%, using glycidyl methacrylate-modified pectin grafted directly onto the fabric surface. Post-wash analysis confirmed the treated fabrics showed promising resistance to repeated washing cycles.
Separation and Identification of Microfibers in the Wastewater of Textile Finishing Process
Researchers collected wastewater samples from textile finishing machinery in February and March 2022, pretreated them with hydrogen peroxide, and used light microscopy, micro-FTIR, and EDX/SEM to identify and characterize microfibers present. They found acrylic and cotton microfibers at concentrations of 0.058 g/L and 0.251 g/L across the two sampling periods, highlighting textile finishing processes as a significant source of microplastic fiber discharge.
Characterization of microfibers released from chemically modified polyester fabrics — A step towards mitigation
This study characterized microfibers released from chemically modified polyester fabrics during abrasion, finding that surface treatments altered fiber release rates and morphology. The results inform strategies to reduce microfiber pollution from synthetic textiles at the manufacturing and use stages.
Aging of textile-based microfibers in both air and water environments
Researchers aged textile-based microfibers under controlled air and water environments over extended periods, characterizing changes in surface chemistry, mechanical properties, and morphology, finding that degradation pathways differed substantially between air and aquatic conditions.
Promoting degradation of polyamide-microplastic fibers using hydroxy radical
Researchers found that hydroxyl radicals generated in water can degrade polyamide microplastic fibers shed from synthetic textiles. This approach offers a potential chemical treatment pathway for removing synthetic fiber microplastics from laundry wastewater before they reach waterways.
A novel method for the isolation, characterisation, and quantification of nanoplastic fibres released from synthetic textiles during laundering
Researchers developed a novel method for isolating, characterising, and quantifying nanoplastic fibres (NPFs) released during laundering of synthetic textiles — including acrylic, nylon, and polyester — enabling fibre size differentiation from the micro to the nano scale. The method addresses a significant gap in textile pollution research by providing a tool to study the understudied nanoplastic fraction of laundry-derived fibre emissions.
From closet to contaminant to control: Unveiling microplastic sources in household textiles and potential for environmental application
Degraded domestic textile fibers were chemically and thermally activated and tested for dye remediation, with ZnCl₂-activated polyurethane and polyester fibers showing the best removal efficiency (up to 87.7%) for anionic dyes, repurposing textile microplastic waste for environmental cleanup.
Reducing microfiber release from polyester fabrics through optimization of spinning process parameters
Researchers identified yarn hairiness — the tiny fibers sticking out from a thread — as the primary driver of microfiber release from polyester fabrics during washing, and showed that selecting the right spinning method (Siro compact spinning) at manufacturing can reduce microplastic shedding by minimizing those protruding fibers at the source.
Microfiber Release to Water, Via Laundering, and to Air, via Everyday Use: A Comparison between Polyester Clothing with Differing Textile Parameters
Researchers measured microfiber release from polyester garments into both wash water and air during everyday wear, finding that release into air was comparable to or exceeded laundry release and was influenced by fabric structure, yarn type, and twist level.
Investigating the influence of yarn characteristics on microfibre release from knitted fabrics during laundering
This study investigated how yarn characteristics such as fiber type, twist, and structure influence the quantity of microfibres released from knitted fabrics during laundering, identifying key design factors that could reduce textile microfiber pollution.
Water repellency of cotton knitted fabrics treated with alkyl ketene dimers
Cotton knitted fabrics soaked in alkyl ketene dimer (AKD) dispersions acquired strong water repellency after curing at 120°C, with SEM revealing flake-like AKD structures on the fibers; the study offers a practical approach to making hydrophilic cotton fabrics water-repellent without fluorinated chemicals.
Detection and Analysis of Microfibers and Microplastics in Wastewater from a Textile Company
Researchers analyzed microfiber and microplastic levels in wastewater from a textile company, finding that the on-site treatment plant removed only 38–65% of microfibers, meaning up to 62% — including acrylic, polyester, and polyamide particles — can escape into receiving waterways.
Effects and Characterization of Environmental Conditions on Microplastic Fibers Release from Synthetic Textile
Researchers investigated how environmental conditions such as moist heat, high-temperature drying, and abrasion affect the release of microplastic fibers from synthetic textiles. The study found that these aging processes significantly increased fiber shedding, highlighting synthetic clothing as a major ongoing source of microplastic contamination in water environments.
Charting a path to catalytic upcycling of plastic micro/nano fiber pollution from textiles to produce carbon nanomaterials and turquoise hydrogen
Researchers demonstrated proof-of-concept for catalytic upcycling of polyester and cotton textile-derived microfibers into structured solid carbon products, using a defined fiber feedstock to establish a pathway for converting fiber pollution into value-added carbon materials.
Scrutinizing the chemical and morphological alterations of microfibers released from household washing machines under varying temperature conditions
This study examined how washing temperature affects the quantity and chemical properties of microfibers released from synthetic textiles in household washing machines, finding that higher temperatures increased fiber release and altered fiber surface chemistry. The results have implications for reducing microplastic pollution from laundry and for textile product design.
Microfiber release from different fabrics during washing
This study quantified microfiber shedding from polyester, polyamide, and acrylic fabrics during washing, finding that fiber release depended on fabric construction and washing conditions, with up to tens of thousands of fibers released per wash.
Textile Recycling’s Hidden Problem: Surface-Modified Fiber Fragments Emitted at Every Stage
Researchers investigated microplastic fiber release during chemical recycling of polyester-cotton blended textiles and found that the dye removal stage generated the highest fiber counts, averaging around 10,055 fibers per gram of textile waste. Alkaline hydrolysis reduced fiber emissions during the treatment stage by nearly 88% compared to acid hydrolysis. The study highlights that textile recycling processes, while essential for sustainability, can themselves be a significant source of microplastic fiber pollution.
Microplastic fibres from synthetic textiles: Environmental degradation and additive chemical content
Researchers studied how common synthetic textile fibers — polyester, polyamide, and polyacrylonitrile — degrade in seawater and freshwater under UV light exposure. They found that these fibers release chemical additives as they break down, with polyester and polyamide releasing particularly concerning levels of plastic-related chemicals into the surrounding water.