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20 resultsShowing papers similar to Exploring Humic Acid as an Efficient and Selective Adsorbent for Lead Removal in Multi-Metal Coexistence Systems: A Review
ClearEnhanced vector transport of microplastics-bound lead ions in organic matter rich water
Researchers evaluated how pristine and aged polyethylene microplastics adsorb Pb2+ ions in water under varying pH, ionic strength, contact time, Pb2+ concentration, and humic acid (HA) concentration, finding that HA enhanced lead adsorption onto aged microplastics and that maximum adsorption occurred around pH 5-6, demonstrating the vector transport potential of microplastics for lead in organic matter-rich waters.
Influence of Organic Matter and Speciation on the Dynamics of Trace Metal Adsorption on Microplastics in Marine Conditions
Researchers evaluated how dissolved organic matter in the form of humic acid influences the adsorption dynamics of essential and toxic trace metals — including cobalt, copper, nickel, zinc, cadmium, and lead — onto polyethylene and polystyrene microplastics under simulated marine conditions. The study found that humic acid altered metal speciation and reduced adsorption onto microplastic surfaces, demonstrating that natural organic matter substantially modifies the role of microplastics as trace metal vectors in the ocean.
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.
Effects of humic acids on the adsorption of Pb(II) ions onto biofilm-developed microplastics in aqueous ecosystems
Biofilm-coated PVC microplastics adsorbed Pb(II) ions at 3.57 mg/g, nearly double the capacity of virgin PVC at 1.85 mg/g, while humic acid increased Pb adsorption on virgin PVC through complexation but decreased adsorption on biofilm-coated PVC by shielding sorption sites.
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.
Effects of humic acid on Pb2+ adsorption onto polystyrene microplastics from spectroscopic analysis and site energy distribution analysis
Researchers investigated how humic acid (HA) affects the adsorption of lead ions onto polystyrene microplastics, finding that higher HA concentrations promoted greater lead adsorption by acting as a bridging molecule between the plastic surface and the metal. Spectroscopic analysis confirmed that HA introduced additional adsorption sites and enhanced the surface affinity of the microplastics for lead.
Advancements in Adsorption Techniques for Sustainable Water Purification: A Focus on Lead Removal
This review surveys recent advances in adsorption techniques for removing lead from contaminated water, covering materials from traditional metal oxides to newer options like chitosan, zeolites, and carbon-based structures. Researchers evaluate how well each material performs and highlight promising alternatives that are more sustainable and cost-effective. While focused on heavy metals rather than microplastics, the study contributes to the broader effort of developing better water purification methods.
Adsorption of typical natural organic matter on microplastics in aqueous solution: Kinetics, isotherm, influence factors and mechanism
Researchers investigated humic acid adsorption onto PVC and PS microplastics, finding that pH, ion species, particle size, and surfactants significantly influenced adsorption capacity through mechanisms including halogen bonding, hydrogen bonding, and pi-pi interactions.
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.
Interactions of microplastics with heavy metals in the aquatic environment: Mechanisms and mitigation
This review synthesized mechanisms of heavy metal adsorption onto microplastics in aquatic environments and evaluated strategies for removing both contaminants simultaneously. The authors found that temperature, salinity, and plastic surface aging govern metal binding, and identified hybrid adsorbent materials as the most promising approach for co-removal of metals and microplastics from water.
Magnetically Separable Humic Acid-Chitin Based Adsorbent as Pb(II) Uptake in Synthetic Wastewater
Researchers synthesized a magnetic humic acid-chitin composite material to adsorb lead (Pb) from synthetic wastewater, achieving high removal efficiency. Magnetically separable adsorbents are being developed for removing microplastics and associated heavy metals from contaminated water.
Magnetite-Functionalized Horse Dung Humic Acid (HDHA) for the Uptake of Toxic Lead(II) from Artificial Wastewater
Scientists synthesized a magnetic material from horse dung-derived humic acid to efficiently remove lead from wastewater, achieving rapid uptake and easy magnetic separation. While focused on heavy metals, magnetic separation technology is also being explored for removing microplastics from water.
Assessing the Impact of Soil Humic Substances, Textural Fractions on the Sorption of Heavy Metals (Cd, Pb)
Researchers assessed how soil humic substances and textural fractions influence the sorption of cadmium and lead in different Slovak soil types. The study found that the type and quantity of humic materials significantly affect heavy metal retention, which is relevant to understanding how contaminants interact with soil-bound microplastics.
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.
Effect of microplastics on the adherence of coexisting background organic contaminants to natural organic matter in water
Researchers examined how microplastics affect the binding of organic contaminants (PCBs and hydroxy PCBs) to humic acid in water, finding that microplastics caused contaminants to migrate from humic acid to plastic surfaces. This redistribution effect could alter the bioavailability and environmental risk of co-occurring organic pollutants.
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.
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.
The regulation of the environmental behavior of NPs by humic acid: A review
This review examines how humic acid, a naturally occurring substance in soil and water, interacts with nanoplastics in the environment. Researchers found that humic acid significantly influences how nanoplastics behave, move, and exert toxic effects, suggesting that traditional toxicity assessments based on pure nanoplastics alone may not reflect real-world exposure conditions.
Further research on the impacts of humic acid in the aggregation of nanoplastics: The roles of molecular weight and surface functionalization
Researchers studied how humic acid — a natural compound found in soil and water — coats nanoplastic particles and changes how they clump together, finding that larger humic acid molecules create thicker coatings that keep nanoplastics suspended and dispersed rather than settling. This matters because dispersed nanoplastics travel farther through water systems and are more likely to be ingested by organisms.
Flocculation Properties of Acrylamide‐Grafted Tamarind Polysaccharide on Microplastics and Heavy Metals Ions
Researchers created a modified polysaccharide derived from tamarind — a natural plant material — that acts as an effective flocculant, clumping together PVC microplastics and lead ions from water so they can be removed. Under optimized conditions, the material removed over 91% of PVC microplastics and over 93% of lead ions, with even better performance when both contaminants were present together. This bio-based flocculant offers a sustainable option for treating water contaminated with both microplastics and heavy metals simultaneously.