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Papers
20 resultsShowing papers similar to Application of Nanomaterials in the Degradation of Micro and Nano Plastics
ClearRole of Nanotechnology in Plastic and Microplastic Management
This review examines how nanotechnology can enhance plastic and microplastic degradation, describing how nanomaterials can modify microbial metabolic pathways to improve biodegradation rates and how photocatalytic approaches can break down plastics into low-molecular-weight intermediates suitable for use as chemical feedstocks.
Novel Acumens into Biodegradation: Impact of Nanomaterials and Their Contribution
This review examines how nanomaterials can enhance the biodegradation of pollutants, including plastics, in the environment. Nanomaterial-assisted biodegradation offers a potential strategy for accelerating the breakdown of plastic waste before it fragments into microplastics.
Nanotechnology for the Remediation of Plastic Wastes
This review examines nanotechnology-based approaches for remediation of plastic waste, covering methods to address the growing environmental threat posed by microplastics and nanoplastics as persistent pollutants derived from degrading larger plastic debris.
Degradation of Micro- and Nano-Plastics by Photocatalytic Methods
This paper reviews photocatalytic methods — using light-activated catalysts — as a way to break down micro- and nano-plastics in the environment. These approaches offer a promising path toward degrading persistent plastic particles that accumulate in marine and drinking water systems.
Nanomaterials for microplastic remediation from aquatic environment: Why nano matters?
This review examines how nanomaterials such as photocatalysts, adsorbents, and membrane filters can be used to remove microplastics from aquatic environments, highlighting why nanoscale properties offer advantages over conventional remediation approaches.
Challenges and opportunities in bioremediation of micro-nano plastics: A review.
This review examines biological approaches to removing micro- and nanoplastics from the environment, focusing on microbial degradation and bioremediation strategies. While bioremediation holds promise, challenges remain in identifying microbes capable of degrading common plastic types and scaling these processes for practical environmental cleanup.
Photocatalytic Perception for Degradation of Macro- and Micro-plastics
This review examines photocatalytic approaches for degrading both macro- and micro-plastics, surveying semiconductor-based and other photocatalytic systems capable of breaking down persistent plastic polymers in aquatic and terrestrial environments. The paper evaluates the mechanisms, efficiency, and scalability of photocatalysis as a remediation technology alongside conventional plastic waste management strategies.
Nano-based remediation strategies for micro and nanoplastic pollution
This review covers how nanomaterial-based technologies can be used to remove microplastics from the environment, including methods using magnetic nanoparticles, photocatalysts, and membrane filters. While current physical, chemical, and biological removal methods each have limitations, nanomaterials can enhance their effectiveness by targeting smaller plastic particles that traditional methods miss. Better removal technologies could ultimately reduce human exposure to microplastics in drinking water and food.
Nanotechnology in Plastic Degradation
This review examines how nanotechnology can enhance plastic biodegradation, with nanoparticles improving microbial metabolic efficiency for polythene degradation, while also being incorporated into bioplastics to improve their poor thermal and mechanical properties relative to conventional plastics.
Engineered nanocatalysts for degradation and valorisation of micro/nanoplastics
This review explored how engineered nanocatalysts can break down micro- and nanoplastics and convert them into useful products. Researchers highlighted several promising technologies, including microrobots, nanozymes, and solar-powered systems that can efficiently degrade persistent plastic particles. The study suggests that catalytic approaches offer a pathway toward both cleaning up plastic pollution and supporting a circular economy by turning waste into valuable materials.
Innovative Approaches to Microplastic and Nano-plastic Biodegradation
This review covers innovative biotechnological approaches to microplastic and nanoplastic biodegradation, examining the origins of these particles from larger plastic waste and intentionally manufactured microbeads. The authors assess promising biological and enzymatic strategies for accelerating breakdown of persistent plastic polymers in environmental and engineered systems.
Mechanisms and the Engineering Approaches for the Degradation of Microplastics
This review provided a comprehensive overview of current microplastic degradation methods, including mechanical, chemical, photocatalytic, and biological approaches, evaluating engineering strategies for efficient microplastic treatment and removal.
Catalytic and biocatalytic degradation of microplastics
This review covers the current state of breaking down microplastics using catalysts and biological agents including enzymes, metals, nanomaterials, and microorganisms. While some approaches show promise for degrading certain plastic types, the field is still developing standardized methods for measuring how well these techniques work. Finding effective ways to break down microplastics is critical for reducing the environmental and health burden of plastic pollution.
Nanoparticle-Based Bioremediation Approach for Plastics and Microplastics
This review explores how nanoparticle-enhanced bioremediation approaches can help address plastic and microplastic pollution. Researchers found that combining biological degradation by bacteria and fungi with engineered nanoparticles can improve the efficiency of breaking down various plastic polymers. The study suggests that these hybrid bioremediation strategies offer a promising eco-friendly pathway for mitigating plastic contamination in the environment.
Photodegradation of microplastics through nanomaterials: Insights into photocatalysts modification and detailed mechanisms
This review explores how nanomaterial-enhanced photocatalysts can break down microplastics that conventional water treatment fails to remove. The paper details key strategies like element doping and heterojunction construction that improve degradation efficiency, and explains the underlying mechanisms involving free radical formation and singlet oxygen oxidation.
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.
Photocatalytic Technologies for Transformation and Degradation of Microplastics in the Environment: Current Achievements and Future Prospects
This review examines photocatalytic technologies that use light-activated materials to break down microplastics in the environment. Various catalysts can generate reactive oxygen species that degrade plastic polymers into simpler, less harmful molecules. The authors assess the strengths and limitations of different photocatalytic approaches and highlight the need for scalable solutions that work under real-world environmental conditions.
Photocatalytic Degradation and Remediation of Microplastics
This review chapter examines photocatalysis as a remediation strategy for microplastic pollution in aquatic and terrestrial environments, describing how solar energy conversion drives chemical reactions that degrade plastic particles. The authors assess the current state of photocatalytic methods, their mechanisms, and their potential for sustainable microplastic removal.
Countering microplastics pollution with photocatalysis: Challenge and prospects
This review summarized the use of photocatalysis for degrading microplastics, covering catalyst types, reaction mechanisms, and operational parameters, and discussing challenges including the stability of highly polymerized plastics and prospects for scaling photocatalytic treatment to address environmental microplastic pollution.
Efficiency of Hybrid Materials for Photocatalytic Degradation of Micro‐ and Nano‐Plastics
Researchers reviewed how hybrid materials — combinations of multiple substances engineered at the nanoscale — can serve as highly effective photocatalysts to break down microplastics and nanoplastics using light energy. These multi-functional materials improve electron separation and reaction efficiency compared to single-component catalysts, representing a promising technological pathway for removing persistent plastic particles from the environment.