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61,005 resultsShowing papers similar to Recent Studies of Membranes for Liquids Separation and Water Treatment
ClearRecent 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.
Membrane Technologies at the Frontier: A Review of Advanced Solutions for Microplastics and Emerging Contaminants in Wastewater
This review evaluates advanced membrane-based technologies for removing microplastics and emerging contaminants from wastewater, covering mechanisms such as size exclusion, adsorption, and biodegradation. Researchers identified membrane fouling as the primary constraint on operational efficiency, with different fouling types contributing to reduced water flow and increased energy costs. The study outlines future directions including intelligent membranes, AI-driven monitoring systems, and circular economy approaches to sustainable wastewater treatment.
Multidisciplinary Advances in Efficient Separation Processes
This book chapter reviews advances in industrial separation processes, including membrane technologies and wastewater treatment methods aimed at removing micropollutants and microplastics. Improving these processes is important for reducing plastic contamination in treated water discharged to the environment.
Innovative Physical and Chemical Strategies for the Modification and Development of Polymeric Microfiltration Membranes—A Review
This review covers physical and chemical strategies for modifying polymeric microfiltration membranes to improve their performance and reduce fouling in water, dairy, beverage, and pharmaceutical processing. While not exclusively focused on microplastics, these membrane technologies are directly relevant as filtration barriers for removing micro- and nanoplastic particles from treated water.
Review of New Approaches for Fouling Mitigation in Membrane Separation Processes in Water Treatment Applications
This review examined new antifouling strategies for membrane separation processes in water treatment, analyzing how organic matter including nano/microplastics, inorganic particles, and biological matter cause membrane fouling, and evaluating nanomaterial-based and other emerging mitigation approaches.
The Potential Role of Membrane Technology in the Removal of Microplastics from Wastewater
This review examines membrane filtration as a technology for removing microplastics from wastewater, finding it promising but limited by issues of fouling and chemical instability. Improving membrane technology could significantly reduce the amount of microplastics discharged into waterways from treatment plants.
A review of microplastic removal from water and wastewater by membrane technologies
This review examines how membrane filtration technologies can remove microplastics from drinking water and wastewater. Researchers found that advanced membranes like nanofiltration, reverse osmosis, and membrane bioreactors are among the most effective methods for capturing microplastic particles that conventional treatment plants miss. The study compares membrane approaches with other removal methods and discusses the challenges of membrane fouling caused by microplastic accumulation.
Optimized Polymeric Membranes for Water Treatment: Fabrication, Morphology, and Performance
This review examines advances in polymer membrane design for water purification, focusing on how chemical functionalization and fabrication methods determine membrane performance. Researchers highlight promising developments incorporating metal-organic frameworks, covalent organic frameworks, and graphene into polymer membranes for selectively removing toxic metals and chemicals. The study emphasizes that choosing the right polymer chemistry and morphology is critical for developing efficient water treatment systems.
Filtration Solutions for Microplastic Mitigation: Cutting-Edge Filtration Technologies and Membrane Innovations for Environmental Protection
This review focused on membrane-based filtration technologies—including microfiltration, ultrafiltration, and nanofiltration—as strategies for removing microplastics from water. The authors evaluated removal efficiencies across membrane types and concluded that while membranes show strong performance, fouling and operational costs remain barriers to large-scale deployment.
Advancements in Sustainable Membrane Technologies for Enhanced Remediation and Wastewater Treatment: A Comprehensive Review
This review covers membrane filtration technologies—reverse osmosis, nanofiltration, and ultrafiltration—as methods for removing contaminants from water, with relevance to microplastic and nanoplastic removal from drinking water and wastewater. Advancing membrane-based treatment is critical for reducing the microplastic load in treated water that humans and ecosystems are ultimately exposed to.
A multidimensional study of wastewater treatment
This review covers the full range of wastewater treatment approaches, from physical and chemical methods to biological and membrane-based technologies. The paper summarizes how different contaminant types — including microplastics — are handled by various treatment systems. It serves as a broad reference for understanding current wastewater management capabilities and limitations.
Understanding emerging contaminants in water and wastewater: A comprehensive review on detection, impacts, and solutions
This review covers emerging contaminants in water including pharmaceuticals, PFAS, microplastics, and nanomaterials that escape conventional water treatment and persist in the environment. It evaluates advanced detection techniques and newer treatment methods such as membrane filtration, advanced oxidation, and bioremediation to address these pollutants that pose ongoing risks to public health.
A Brief Review of Treatment Methods for Certain Emerging Contaminants in Domestic and Industrial Effluents
This review summarizes emerging contaminant treatment methods for domestic and industrial effluents, covering advanced oxidation, membrane filtration, adsorption, and biological approaches for removing pharmaceuticals, microplastics, and other persistent pollutants.
Removal of microplastics and nanoplastics from urban waters: Separation and degradation
This review summarizes recent advances in removing micro- and nanoplastics from urban waters, covering both separation technologies like membrane filtration and degradation approaches including photocatalysis and advanced oxidation processes.
Current Status and Advancement of Nanomaterials within Polymeric Membranes for Water Purification
This review examines advances in nanomaterial-enhanced polymeric membranes for water purification, including the removal of contaminants like heavy metals, organic pollutants, and microplastics. Researchers highlight how integrating materials such as metal nanoparticles, nanofibers, and graphene oxide can improve membrane performance for filtering various waterborne pollutants. The study suggests these technologies hold promise for addressing growing challenges in water contamination.
A review on metal organic frameworks (MOFs) modified membrane for remediation of water pollution
This review covers how metal-organic framework (MOF) materials can be incorporated into membranes to improve filtration of pollutants from contaminated water. The technology shows promise for removing microplastics and chemical contaminants, though most applications remain at laboratory scale.
Modern Wastewater Treatment Technologies: Trends, Problems, and Prospects
This review examines modern wastewater treatment technologies including mechanical, biological, and physicochemical methods, highlighting that conventional systems inadequately remove emerging micropollutants such as pharmaceuticals, pesticides, microplastics, and nanoparticles. The authors identify key barriers to progress including high costs, aging infrastructure, and weak governance, and advocate for integrated approaches combining membrane technologies, nanomaterials, and circular economy principles.
Filtration Solutions for Microplastic Mitigation: Cutting-Edge Filtration Technologies and Membrane Innovations for Environmental Protection
This review covers advances in filtration technologies and membrane innovations for removing microplastics from the environment, examining the performance, limitations, and scalability of approaches including membrane filtration, coagulation, and combined treatment processes.
Nano/microplastics: Fragmentation, interaction with co-existing pollutants and their removal from wastewater using membrane processes
This review explores how nano- and microplastics fragment from larger plastic debris and interact with other pollutants like heavy metals and pharmaceuticals in water environments. Researchers examined how these tiny particles can adsorb hazardous substances onto their surfaces, potentially increasing health risks for humans and aquatic organisms. The study also evaluates membrane-based filtration technologies as promising methods for removing these combined contaminants from wastewater.
Research progress and application exploration of techniques to remove emerging contaminants from water environment
This review summarizes technologies for removing emerging contaminants — including pharmaceuticals, microplastics, and pesticides — from water, covering adsorption, membrane filtration, advanced oxidation, and biological methods. The authors assess the effectiveness and limitations of each approach for real-world water treatment.
Wastewater Treatment Using Membrane Technology
This review covers membrane-based wastewater treatment technologies for removing heavy metals, cyanides, and dyes, evaluating their performance and limitations. Membrane technologies are also increasingly investigated for microplastic removal from wastewater, making this review relevant to the broader challenge of treating complex contaminated water.
Elimination of microplastics from the aquatic milieu: A dream to achieve
Researchers reviewed current methods for eliminating microplastics from aquatic environments, including membrane technologies such as ultrafiltration, nanofiltration, and microfiltration. The study assessed how microplastics interact with toxic organic chemicals, antibiotics, and heavy metals in water, compounding their environmental impact. The review suggests that while various removal technologies show promise, achieving complete elimination of microplastics from water remains a significant challenge.
Membrane Cleaning Technologies for Water Treatment: A Review
Membrane filtration is one of the most effective technologies for removing microplastics from drinking water and wastewater, but membranes clog over time and require regular cleaning to maintain performance. This review evaluates the full range of cleaning methods—from simple water backwashing to ultrasonic treatment, advanced oxidation processes, and electrochemical approaches—comparing their effectiveness at removing different types of fouling without damaging the membrane. Understanding optimal cleaning strategies is important for designing cost-effective, long-lasting filtration systems that can reliably remove microplastics at scale.
Removal of Polypropylene Particle Contaminants Using Membrane Technology to Mitigate Microplastics Pollution in the Environment
Researchers tested the ability of different membrane types to remove polypropylene microplastic particles from water, evaluating separation efficiency under varying conditions. Membranes achieved high removal rates for particles above a threshold size, with performance depending on membrane pore size, material, and operating pressure.