We can't find the internet
Attempting to reconnect
Something went wrong!
Hang in there while we get back on track
Papers
61,005 resultsShowing papers similar to Turning the tide on microplastic pollution: Leveraging the potential of geopolymers for mitigation
ClearPotential improvement in the mechanical performance and thermal resistance of geopolymer with appropriate microplastic incorporation: A sustainable solution for recycling and reusing microplastics
Researchers tested whether microplastics of various sizes could be incorporated into geopolymer, a cement-like construction material, as a way to recycle plastic waste. Adding small amounts of microplastics actually improved the material's strength and heat resistance up to 400 degrees Celsius. This approach offers a potential solution for trapping microplastics in building materials rather than letting them pollute the environment and threaten human health.
Emerging Porous Materials for Adsorptive Removal of Microplastics and Nanoplastics from Aquatic Environments: A Review
This review summarizes recent advances in using porous materials, including sponges, aerogels, hydrogels, metal-organic frameworks, and carbon-based adsorbents, to remove microplastics and nanoplastics from water. Researchers found that adsorption using these materials is a promising, cost-effective approach that outperforms conventional water treatment methods for plastic particle removal. The study identifies key challenges and future research directions for developing practical adsorbents for real-world plastic pollution mitigation.
Microplastic pollutants in water: A comprehensive review on their remediation by adsorption using various adsorbents
This review covers the different materials scientists are developing to filter microplastics out of water, including biochar, activated carbon, sponges, carbon nanotubes, and newer hybrid materials. Each material has trade-offs in terms of cost, effectiveness, and environmental impact, but combining different approaches shows the most promise. The research is important because better water filtration methods could directly reduce the amount of microplastics people consume through drinking water.
Innovations in the Development of Promising Adsorbents for the Remediation of Microplastics and Nanoplastics – A Critical Review
This review evaluates innovative materials being developed to remove microplastics and nanoplastics from polluted water, including carbon-based, metal, polymer, and mineral adsorbents. Researchers compared the effectiveness, advantages, and limitations of each type, finding that adsorption-based approaches show strong promise. The study highlights remaining challenges such as scaling these technologies for real-world water treatment applications.
The Potentiality of Reuse Industrial Waste for Diverse Water Treatment -An Overview
This overview reviews innovative adsorbent materials made from industrial waste that can remove diverse pollutants from wastewater at low cost. While not focused on microplastics specifically, it is relevant to the broader challenge of plastic and chemical pollution remediation in water systems.
Recent innovations in the developments of biopolymer-based materials for the removal of micro- and nanoplastics: A review of performance, critical factors, practicability and knowledge gaps
A review of recent innovations in biopolymer-based materials for various applications assessed how bio-derived polymers are being developed to reduce reliance on fossil-fuel plastics. The transition to biopolymers is relevant to reducing the long-term sources of microplastic pollution.
A brief review on utilizing natural adsorbents for microplastic removal from wastewater: A sustainable approach to environmental protection
Researchers reviewed natural materials like biochar, clay, algae, and agricultural waste as affordable alternatives to synthetic filters for removing microplastics from wastewater, finding some achieved over 80% removal efficiency in the lab, though scaling these methods to real-world treatment systems remains a significant challenge.
The Uptake Potential of Santa Barbara Amorphous Silica/Zeolite Composite for Environmental Microplastics in Wastewater
Researchers developed a silica-zeolite composite material designed to capture and remove microplastics from wastewater. They tested the material's ability to adsorb different types of environmental microplastics and found promising uptake capacity. The study offers a potential new tool for addressing microplastic contamination in water treatment systems.
Nanomaterials for microplastics remediation in wastewater: A viable step towards cleaner water
This review examines how nanomaterials, tiny engineered particles with high surface area and reactivity, can be used to remove microplastics from water more effectively than traditional methods like filtration and sedimentation. While promising, these technologies face challenges including high production costs, potential toxicity of the nanomaterials themselves, and difficulty scaling up from lab to real-world applications. Improving these methods is important because current water treatment often fails to remove the smallest and most harmful microplastic particles.
Assessing Recent Technologies for Addressing Microplastic Pollution and Pushing the Case of Bioremediation as an Attractive Approach
This review assesses current technologies for addressing microplastic pollution, with a focus on bioremediation as a sustainable alternative. Researchers compared physical, chemical, and biological approaches and found that microbial degradation offers distinct advantages in terms of environmental compatibility and cost-effectiveness. The study advocates for increased investment in bioremediation research as a practical strategy for managing microplastic contamination at scale.
Micro- and Nano-Plastics Contaminants in the Environment: Sources, Fate, Toxicity, Detection, Remediation, and Sustainable Perspectives
This review provides a broad overview of micro- and nanoplastic pollution, covering where these particles come from, how they spread through the environment, and the damage they cause to living things including humans. The authors also compare different methods for removing microplastics from the environment, including physical, chemical, and biological approaches. The paper calls for more research and global cooperation to develop better tools for measuring the health risks of plastic pollution.
Microplastics Pollution and its Remediation
This publication reviews the growing problem of microplastic pollution in the environment and explores biological and technological strategies for remediation, including microbial degradation and engineered solutions. It highlights the urgent need for practical cleanup approaches as microplastics continue to accumulate across ecosystems worldwide.
Utilizing nature-based adsorbents for removal of microplastics and nanoplastics in controlled polluted aqueous systems: A systematic review of sources, properties, adsorption characteristics, and performance
This systematic review evaluates how natural materials like agricultural waste and plant-based substances can be used to filter microplastics and nanoplastics from water. The research shows that these nature-based solutions offer a sustainable and effective approach to reducing plastic particle contamination in drinking water and wastewater systems.
Microalgae-based bioremediation of refractory pollutants: an approach towards environmental sustainability
This review examines how microalgae can be used to clean up hard-to-remove pollutants, including microplastics, from contaminated environments. The authors highlight that microalgae-based bioremediation is a sustainable, eco-friendly approach that could help address the growing problem of microplastic pollution in waterways.
A critical review of microplastics and nanoplastics in wastewater: Insights into adsorbent-based remediation strategies
This review analyzes research on removing microplastics and nanoplastics from water using materials that absorb the particles, finding that adsorption is the most widely studied removal method. Carbon-based and metal-based materials currently dominate the research, but plant-based (biopolymer) adsorbents are gaining attention because they are biodegradable and non-toxic. Better removal technologies are critical because conventional water treatment often fails to capture the smallest plastic particles that pose the greatest risk to human health.
Toward the review on sustainable elimination of microplastics: Materials, strategies, and advantages
This review evaluates sustainable approaches for removing microplastics using natural materials — including sponges, gels, enzymes, and microorganisms — comparing their mechanisms, efficiencies, and advantages over conventional chemical removal methods.
Microplastic pollution in marine environments: An in-depth analysis of advanced monitoring techniques, removal technologies, and future challenges
This review provides a comprehensive analysis of microplastic pollution in marine environments, covering sources, ecological impacts, and current monitoring and removal technologies. Researchers examined physical, chemical, and biological methods for microplastic detection and cleanup, including filtration, separation, and hybrid approaches. The study concludes that while progress has been made, significant gaps remain in our ability to effectively monitor and remove microplastics from ocean ecosystems.
Recycling and Management of Microplastic Waste
This review examines recycling and management strategies for plastic waste, describing the technical and economic challenges of reducing plastic pollution and the remediation approaches that have been attempted to address microplastic accumulation in the environment.
Confronting microplastic pollution: integrative approaches for a sustainable future
This mini-review surveys current strategies for combating microplastic pollution, covering physical, chemical, biological, and adsorption-based remediation methods. The study suggests that integrating multiple approaches and advancing biodegradation research will be essential for effectively addressing microplastic contamination across terrestrial and aquatic environments.
Removal of micro- and nano-plastics from aqueous matrices using modified biochar – A review of synthesis, applications, interaction, and regeneration
This review examines how modified biochar materials can be used to remove micro- and nanoplastics from water. Researchers found that chemical functionalization and nanoparticle integration of biochar significantly improve its ability to capture plastic particles through mechanisms like electrostatic interaction and physical adsorption. The study also highlights challenges in regenerating used biochar for sustainable reuse in water treatment applications.
Trends in the applications of biochar for the abatement of microplastics in water
This review examines how biochar can be used to remove microplastics and nanoplastics from water, summarizing recent advances in biochar modification strategies that improve adsorption capacity and minimize secondary pollution risks.
Evaluating the effectiveness of adsorption nano-techniques for microplastic removal: Insights and future prospects
This review evaluates the effectiveness of various adsorbent materials, including activated carbon, bioadsorbents, and advanced nanomaterials, for removing microplastics and nanoplastics from water. Researchers examined key factors like pore size, surface charge, and environmental conditions that influence removal efficiency. The study highlights the need for developing more sustainable and cost-effective adsorbent materials to tackle growing microplastic contamination in water sources.
Nanomaterials for the remediation of microplastics in wastewater
This review evaluates how engineered nanomaterials can be used to capture and break down microplastics in wastewater, highlighting approaches based on metal oxide nanoparticles, carbon-based materials, and magnetic composites. Researchers found that these nanomaterials offer high surface area and reactivity advantages over conventional treatment methods. The study identifies scalability, cost, and potential secondary pollution from the nanomaterials themselves as key challenges to address before widespread adoption.
A review on strategies for the removal and degradation of microplastics from aquatic environments: Pros, cons, policies perspectives, and life cycle and economic assessment
Researchers reviewed strategies for removing and degrading microplastics from aquatic environments, including sand filtration, adsorption, and membrane technologies. The study evaluates the advantages, challenges, and practical solutions for each approach, alongside policy perspectives and life cycle economic assessments to guide future remediation efforts.