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 Comparative analysis of kinetics and mechanisms for Pb(II) sorption onto three kinds of microplastics
ClearPb(II) uptake onto nylon microplastics: Interaction mechanism and adsorption performance
Researchers investigated how aged nylon microplastics adsorb lead(II) ions from water, finding that surface weathering increased adsorption capacity and that the process followed pseudo-second-order kinetics. The study clarifies the mechanism by which microplastics can act as vectors for heavy metal contamination in aquatic environments.
Insights Into the Adsorption Behavior of Polyethylene Microplastics Towards Lead(II) Ions
Researchers investigated the adsorption behavior of lead(II) ions onto polyethylene microplastics in freshwater environments by systematically varying initial Pb(II) concentration, pH, and residence time, using scanning electron microscopy and other characterization methods to elucidate the interaction dynamics and sorption mechanisms between this common metal contaminant and microplastic surfaces.
Study on the Adsorption Behavior and Mechanism of Heavy Metals in Aquatic Environment before and after the Aging of Typical Microplastics
Researchers investigated the adsorption behavior and mechanisms of heavy metals by typical microplastics before and after environmental aging, finding that aging significantly alters microplastics' surface properties and capacity to bind metals such as cadmium and lead in aquatic systems.
Investigation of Heavy Metal Adsorption on Microplastics
Researchers investigated the adsorption of lead (Pb) and aluminium (Al) onto polyethylene terephthalate, polyamide, and ethylene vinyl acetate microplastics, finding that pH, contact time, initial metal concentration, and temperature all significantly affect adsorption capacity. Experimental data were best described by Langmuir and Freundlich isotherm models, confirming that microplastics act as vectors for heavy metal contaminants in aquatic environments.
Adsorption of lead(II) onto PE microplastics as a function of particle size: Influencing factors and adsorption mechanism
Researchers studied how lead ions attach to polyethylene microplastics of different sizes in water. They found that smaller microplastic particles had greater capacity to adsorb lead, primarily through chemical bonding mechanisms like hydrogen bonding and surface complexation. The findings suggest that microplastics in the environment can act as carriers for toxic heavy metals, with smaller particles posing a greater risk.
Mechanistic description of lead sorption onto nanoplastics
Researchers investigated the mechanisms by which nanoplastics in the environment adsorb lead and other metal contaminants. The study found that despite growing recognition of nanoplastic presence in ecosystems, the processes by which these tiny particles carry and transport metals remain poorly understood. The findings contribute to a better understanding of how nanoplastics may serve as vectors for spreading heavy metal contamination through the environment.
Mechanism analysis of heavy metal lead captured by natural-aged microplastics
The mechanism by which naturally aged microplastics capture lead (Pb(II)) from aqueous solution was investigated by comparing pristine and aged particles. Aged microplastics adsorbed more Pb(II) than pristine ones, with weathering-induced surface oxidation and increased oxygen-containing functional groups driving the enhanced metal capture capacity.
Adsorption of three bivalent metals by four chemical distinct microplastics
Researchers measured the sorption of copper, cadmium, and lead onto four types of microplastic particles — including chlorinated PE, PVC, and two PE variants — finding that higher crystallinity and surface area drove greater metal adsorption, and that all four plastics had different capacities for each metal.
Investigation of the adsorption behavior of Pb(II) onto natural-aged microplastics as affected by salt ions
Researchers found that naturally aged microplastics adsorb significantly more lead than virgin microplastics, and that calcium chloride in solution strongly inhibits lead adsorption, indicating that environmental weathering and water chemistry alter contaminant transport.
The potential of microplastics as carriers of metals
Five types of microplastics were tested for their ability to adsorb heavy metals (Cd, Co, Cr, Cu, Ni, Pb, Zn) in different water matrices, finding significant adsorption of lead, chromium, and zinc—especially on polyethylene and PVC—with surface area and porosity as key drivers. The study identifies microplastics as potential vectors for heavy metal transport and transfer through aquatic food chains.
Microplastics as adsorbent for Pb2+ and Cd2+: A comparative study of polypropylene, polyvinyl chloride, high-density polyethylene, and low-density polyethylene
Researchers compared how four common types of microplastics adsorb lead and cadmium heavy metals in aquatic environments. The study found that polypropylene had the highest adsorption capacity for both metals, with oxygen-containing functional groups playing a key role in the adsorption process, suggesting that different microplastic types pose varying levels of environmental risk as heavy metal carriers.
Metal adsorption by microplastics in aquatic environments under controlled conditions: exposure time, pH and salinity
Scientists systematically varied pH, salinity, and exposure time during metal adsorption experiments on different microplastic types, finding that pH had the greatest influence on metal uptake, with higher pH favoring adsorption of copper, lead, and cadmium onto most tested polymers.
Microplastics inhibit lead binding to sediment components: Influence of surface functional groups and charge environment
Researchers systematically investigated interactions among lead, polystyrene microplastics, and sediment components to understand how microplastics affect heavy metal behavior in aquatic environments. The study found that polystyrene significantly inhibited lead adsorption to sediment by competing for binding sites, reducing lead uptake by up to 28%, which suggests that microplastics could increase the mobility of toxic metals in contaminated waterways.
Kinetics and Size Effects on Adsorption of Cu(II), Cr(III), and Pb(II) Onto Polyethylene, Polypropylene, and Polyethylene Terephthalate Microplastic Particles
Researchers investigated how copper, chromium, and lead ions adsorb onto polyethylene, polypropylene, and PET microplastic particles of different sizes. The study found that smaller microplastic particles had greater adsorption capacity for heavy metals, with lead showing the highest adsorption levels, particularly on PET particles, suggesting increased environmental risk when tiny microplastics and heavy metals coexist.
Enhancing Pb Adsorption on Crushed Microplastics: Insights into the Environmental Remediation
Researchers found that crushed microplastics generated during plastic recycling have significantly higher capacity to absorb lead than primary microplastics, due to their greater surface area and more reactive surfaces. Factors like particle size, water pH, salinity, and biofilm formation all influenced how much lead the particles could adsorb. The study raises concerns that the recycling process itself may create a secondary environmental hazard by producing microplastics that more efficiently concentrate toxic heavy metals.
Study on the capability and characteristics of heavy metals enriched on microplastics in marine environment
Laboratory and field experiments examined heavy metal adsorption on five plastic types (PVC, PP, PE, PA, POM), finding that PVC and PP had the highest adsorption capacity for lead and manganese, with field results showing that PP adsorbed metals at concentrations orders of magnitude higher than co-adsorbed PAHs. The study provides direct comparative data on microplastic-metal interactions across polymer types in marine environments.
Microplastics as a vehicle of heavy metals in aquatic environments: A review of adsorption factors, mechanisms, and biological effects
This review summarizes how microplastics in water can absorb and carry toxic heavy metals like lead and cadmium, making them more dangerous to aquatic life than either pollutant alone. Environmental factors such as water acidity, salinity, and organic matter influence how much metal sticks to microplastic surfaces. Since contaminated seafood is a major source of human exposure, understanding these interactions is important for assessing health risks.
Partitioning of chemical contaminants to microplastics: Sorption mechanisms, environmental distribution and effects on toxicity and bioaccumulation
This review critically examines how chemical contaminants like persistent organic pollutants and heavy metals sorb onto microplastic surfaces in the environment. Researchers found that while microplastics can concentrate pollutants at levels far above surrounding water, the actual contribution of microplastics to contaminant transfer into organisms may be less significant than direct exposure from water and food. The study calls for more realistic experimental designs to clarify the true risk.
Adsorption behaviour of accelerated UV aged PET and PP microplastics towards Pb(II) under varying pH, temperature, and salinity conditions
UV aging causes PET and PP microplastics to adsorb significantly more lead (Pb) from water, with the extent varying by pH, temperature, and salinity. This means weathered microplastics in the environment may carry greater toxic metal loads than virgin plastic, amplifying their hazard to ecosystems and human health.
Long-Term Sorption of Metals Is Similar among Plastic Types: Implications for Plastic Debris in Aquatic Environments
Researchers deployed five types of common plastic in San Diego Bay for up to 12 months and measured how much metal accumulated on each type. They found that all plastics accumulated similar concentrations of metals over the long term, regardless of polymer type, suggesting that metal sorption is driven more by surface biofilm formation than by plastic chemistry. The findings indicate that any type of plastic debris in aquatic environments can become a carrier for potentially toxic metals.
Adsorption characteristics of cadmium onto microplastics from aqueous solutions
Laboratory adsorption experiments characterized how cadmium is taken up by microplastics of different polymer types from aqueous solutions, finding adsorption capacity varied significantly with polymer chemistry, particle size, and solution conditions. The results help predict how microplastics in contaminated waterways accumulate and transport cadmium, a highly toxic heavy metal.
Comparison of lead adsorption on the aged conventional microplastics, biodegradable microplastics and environmentally-relevant tire wear particles
Researchers compared how different types of aged microplastics, including tire wear particles and biodegradable polylactic acid, adsorb the heavy metal lead from water. The study found that aging significantly increased adsorption capacity across all types, with tire wear particles showing the highest lead uptake, and that environmental factors like humic acid concentration had complex effects on the adsorption process.
Interaction of Pb(II) with microplastic-sediment complexes: Critical effect of surfactant
Researchers investigated how surfactants affect the ability of microplastic-sediment complexes to adsorb lead (Pb) in river environments. The study found that surfactants significantly altered adsorption behavior, with anionic surfactants increasing lead uptake while nonionic surfactants decreased it, suggesting that surfactant presence in polluted waters can change how heavy metals interact with microplastics in sediments.
Uptake of Pb(II) onto microplastic-associated biofilms in freshwater: Adsorption and combined toxicity in comparison to natural solid substrates
This study examined how biofilms that form on microplastics in freshwater lakes affect the absorption of lead, a toxic heavy metal. Researchers found that biofilm-coated microplastics absorbed significantly more lead than bare plastic particles, and the combination of lead and microplastic biofilms was more toxic to water fleas than either pollutant alone.