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20 resultsShowing papers similar to Marine microplastics fuel long-range transport of radioactive nuclides: A review
ClearMicroplastic-radionuclide complexes: Diffusion mechanisms and multidimensional threats
This review examined how microplastics can bind with radioactive materials in the ocean, creating microplastic-radionuclide complexes that spread contamination across regions. Researchers found that microplastics facilitate the long-distance transport of radionuclides, while the radiation can intensify the toxic effects of the plastic particles on marine organisms. The combined threat is particularly relevant given ongoing concerns about radioactive wastewater discharge into marine environments.
A Preliminary Study on the “Hitchhiking” of Radionuclides on Microplastics: A New Threat to the Marine Environment from Compound Pollution
This preliminary study examined whether radionuclides can adsorb onto microplastic surfaces and be transported through the environment alongside them, identifying the physicochemical properties of microplastics that facilitate radionuclide hitchhiking and the associated contamination risks.
Microplastics as vectors of radioiodine in the marine environment: A study on sorption and interaction mechanism
Researchers investigated microplastics as potential vectors of radioiodine in the marine environment, finding that different polymer types exhibited varying sorption capacities for radioiodine, revealing a previously unstudied pathway for radionuclide transport.
Unfolding the interaction of radioactive Cs and Sr with polyethylene-derived microplastics in marine environment
Researchers investigated how polyethylene microplastics in the marine environment interact with radioactive cesium and strontium. They found that as microplastics age in seawater and develop biofilms, their ability to absorb these radioactive elements increases significantly. The study provides evidence that microplastics could act as previously unrecognized carriers of radioactive contamination in ocean environments.
The interaction of two emerging pollutants, radionuclides and microplastics: In-depth thermodynamic studies in water, seawater, and wastewater
Laboratory experiments measured how polyurethane and polylactic acid microplastics adsorb radioactive uranium and americium from water under conditions mimicking seawater and wastewater. The results show that microplastics can accumulate radionuclides from contaminated water environments, raising the possibility that plastic particles could act as unexpected carriers of radioactive contamination through aquatic food webs.
Microplastics and disposable face masks as “Trojan Horse” for radionuclides pollution in water bodies – A review with emphasis on the involved interactions
Researchers reviewed how microplastics and disposable face masks can adsorb radioactive particles (radionuclides like cesium-137 and uranium) and carry them through water environments, potentially concentrating radiation in the food chain. Key factors affecting this process include plastic type, particle size, and water chemistry, with some polymers showing adsorption partition coefficients as high as 2670 L/kg.
PET plastics as a Trojan horse for radionuclides
Researchers discovered that PET plastic bottles collected near a phosphate fertilizer plant had accumulated natural and artificial radionuclides, demonstrating that littered plastics can act as carriers for radioactive contaminants and pose potential health risks.
Unfolding the interaction of radioactive Cs and Sr with polyethylene-derived microplastics in marine environment
A mesocosm study examined how radioactive cesium and strontium interact with pristine, radiation-exposed, and marine-weathered polyethylene microplastics, finding that environmental aging—through biofilm formation and surface roughening—significantly increased the plastic particles' capacity to sorb radioactive contaminants.
Biofilm-enhanced adsorption of strong and weak cations onto different microplastic sample types: Use of spectroscopy, microscopy and radiotracer methods
Researchers used radiotracer, spectroscopy, and microscopy methods to show that biofilm-coated environmental plastics adsorb radioactive cesium and strontium — radionuclides associated with nuclear releases — though at rates much lower than natural sediments, confirming that plastics act as a minor but measurable sink for environmental radioactivity.
Controlled Release of Radioactive Water from the Fukushima Daiichi Nuclear Power Plant: Should We Be Concerned?
This paper discusses the controlled release of radioactive water from the Fukushima nuclear disaster site into the ocean, raising concerns about seafood safety and long-term environmental health effects. While focused on radioactive contamination rather than microplastics, the study is relevant because it highlights how ocean pollutants can accumulate in marine life and move up the food chain to humans. Both radioactive materials and microplastics share this pathway of exposure through seafood consumption.
Polyethylene terephthalate (PET) microplastics as radionuclide (U-232) carriers: Surface alteration matters the most
Researchers investigated how surface alteration of PET microplastics affects their ability to carry radioactive uranium-232. The study found that biofilm formation on PET surfaces dramatically increased radionuclide adsorption efficiency compared to pristine plastic, suggesting that environmentally weathered microplastics may play a more significant role in transporting radioactive contaminants through aquatic systems.
Initial data on adsorption of Cs and Sr to the surfaces of microplastics with biofilm
Researchers measured adsorption of radiocesium and radiostrontium onto weathered microplastics deployed in freshwater, estuarine, and marine environments, finding that distribution coefficients were approximately two to three orders of magnitude lower than for sediment reference values. Despite the lower adsorption, the buoyancy and mobility of plastics suggest they may still function as a significant radionuclide reservoir in aquatic systems.
A new approach to extracting biofilm from environmental plastics using ultrasound-assisted syringe treatment for isotopic analyses
Researchers developed an ultrasound-assisted syringe extraction method for recovering biofilms from environmental plastic debris, enabling stable carbon and nitrogen isotope analysis and radiocesium quantification, and found that river-mouth plastisphere biofilms in Japan carried up to 820 Bq/kg of radiocesium, demonstrating that plastic-associated biofilms can serve as vectors for radionuclide transport in coastal environments.
Americium Sorption by Microplastics in Aqueous Solutions
Researchers investigated americium sorption by polyamide and polyethylene microplastics in both deionized water and seawater, tracing interactions with Am-241 isotope and examining the effects of pH and solution composition on sorption efficiency over time. The study found that microplastic type and aqueous matrix composition significantly influenced radionuclide uptake, with implications for the transport of radioactive contaminants in marine environments.
The Interaction of Two Emerging Pollutants, Radionuclides and Microplastics: In-Depth Thermodynamic Studies in Water, Seawater, and Wastewater
This study examined how two radioactive isotopes — uranium-232 and americium-241 — interact with polyurethane and polylactic acid microplastics in freshwater, seawater, and wastewater under varying pH and temperature conditions. Microplastics were found to adsorb both radionuclides, with temperature and pH strongly influencing the binding, though natural water chemistry reduced adsorption efficiency significantly. The findings raise concern that microplastics in nuclear-adjacent or contaminated water bodies could act as carriers, concentrating and potentially transporting radioactive pollutants through aquatic systems.
An effective method to assess the sorption dynamics of PCB radiotracers onto plastic and sediment microparticles
Scientists developed a radiotracer method using PCB isotopes to precisely measure how quickly toxic chemicals sorb onto microplastics and sediment particles in seawater. Understanding sorption-desorption rates is critical for predicting how much toxic chemical exposure marine organisms receive from microplastic ingestion.
Application of nuclear techniques to environmental plastics research
This review examines how nuclear techniques — including neutron activation analysis and isotope tracing — can be applied to environmental plastics research to trace polymer sources, measure contaminant uptake, and study degradation pathways. Nuclear methods offer unique analytical capabilities for addressing specific questions about microplastic behavior that conventional approaches cannot resolve.
Research progress on sources, harms and countermeasures of marine pollution
This review explores three major categories of marine pollution: nuclear contamination from Japan's nuclear power plant discharges, ocean acidification from rising carbon dioxide levels, and microplastic pollution. Researchers discuss the harms each poses to marine ecosystems and human health, along with proposed countermeasures. The study calls for international cooperation, stricter oversight, and innovation in detection and removal technologies to protect the global ocean environment.
Microplastics as contaminants in the marine environment: A review
This review synthesized the state of knowledge on microplastics as marine contaminants, covering their sources, pathways, distribution, biological uptake, and potential ecological and toxicological effects.
The effect of temperature on the U-232 and Am-241 adsorption by PN6 microplastics in aqueous solutions.
Researchers investigated the effect of temperature on the adsorption of uranium-232 and americium-241 by polyamide-6 (PN6) microplastics in aqueous solutions, including seawater and wastewater, at picomolar concentrations. The study found that temperature significantly influences radionuclide uptake by microplastics, with implications for the transport and fate of radioactive contaminants in aquatic environments.