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61,005 resultsShowing papers similar to Microplastics InfluenceDissolved Organic Matter TransformationMediated by Microbiomes in Soil Aggregates
ClearMicroplastics InfluenceDissolved Organic Matter TransformationMediated by Microbiomes in Soil Aggregates
A 450-day incubation experiment found that microplastics altered dissolved organic matter transformation in different soil aggregate fractions by modifying microbial community composition and activity, potentially affecting long-term soil carbon dynamics. (Duplicate record of ID 10767.)
Microplastics Influence Dissolved Organic Matter Transformation Mediated by Microbiomes in Soil Aggregates
Researchers conducted a 450-day experiment to study how microplastics alter the transformation of dissolved organic matter within soil aggregates, a process critical for soil stability and fertility. They found that microplastics destabilized organic matter in larger soil clumps while increasing its chemical complexity in smaller ones, with biodegradable plastics having the strongest effects. These changes were driven by shifts in microbial communities, suggesting that microplastic pollution could fundamentally alter how carbon cycles through agricultural soils.
Diverse Impactsof Microplastic-derived DissolvedOrganic Matter at Environmentally Relevant Concentrations on SoilDissolved Organic Matter Transformation
Researchers examined how dissolved organic matter derived from agricultural microplastic mulches affects soil DOM transformation in yellow and black soils at environmentally relevant concentrations. They found that microplastic-derived DOM altered soil DOM dynamics in ways that could affect nutrient cycling and soil ecosystem function even at low, realistic exposure levels.
Microplastic Effects on Soil Aggregation in Sterilized and Non‐Sterilized Soils
Researchers tested how microplastics affect soil aggregation in both sterilized and biologically active soils, finding that microplastic effects on aggregate stability were strongly mediated by the presence of soil microorganisms. Biologically active soils showed different responses than sterile soils, highlighting the role of the soil microbiome.
MicrobialPhysiologicalAdaptation to BiodegradableMicroplastics Drives the Transformation and Reactivity of DissolvedOrganic Matter in Soil
Researchers added virgin and aged polylactic acid and polyhydroxyalkanoate microplastics to agricultural soils and found that microbial physiological adaptation to biodegradable plastics significantly altered the transformation and reactivity of dissolved organic matter over a 56-day incubation period.
Microplastic effects on soil system parameters: a meta-analysis study
Microplastics in soil did not significantly affect dissolved organic carbon, nutrient availability, microbial diversity, or crop biomass, but they did significantly increase soil microorganism abundance and decrease water-stable macro-aggregates, pointing to soil structure degradation as the primary concern.
Comparing the long-term responses of soil microbial structures and diversities to polyethylene microplastics in different aggregate fractions
Long-term soil incubation with polyethylene microplastics found that MPs altered aggregate stability, inhibited soil enzyme activities, and changed microbial community structure and diversity differently across soil aggregate size fractions, with effects persisting over time.
Spatiotemporal heterogeneous effects of microplastics input on soil dissolved organic matter (DOM) under field conditions
Researchers conducted a long-term field experiment and found that microplastic inputs have spatiotemporally heterogeneous effects on soil dissolved organic matter (DOM), with implications for soil carbon dynamics under increasing terrestrial plastic contamination.
Microplastic coupled with soil dissolved organic matter mediated changes in the soil chemical and microbial characteristics
Researchers conducted a two-month incubation experiment to study how polyethylene microplastics of different sizes and concentrations affect soil carbon composition and microbial communities. They found that microplastics altered the dissolved organic matter in soil and shifted how microbial communities utilized carbon sources. The study suggests that microplastic accumulation in agricultural soils may have cascading effects on soil health and nutrient cycling.
Effects of Microplastics and Organic Fertilizer Regulation on Soil Dissolved Organic Matter Evolution
This study examined how microplastic addition to soil affects dissolved organic matter (DOM) evolution, focusing on the interactions between microplastics as carbon sources and organic fertilizer. Microplastics altered DOM composition and quantity, with effects on soil carbon cycling that varied by plastic type and organic fertilizer combination, suggesting complex interactions between plastic pollution and soil amendment practices.
Microplastics Can Inhibit Organic Carbon Mineralization by Influencing Soil Aggregate Distribution and Microbial Community Structure in Cultivated Soil: Evidence from a One-Year Pot Experiment
Researchers conducted a one-year pot experiment to study how different types and concentrations of microplastics affect soil carbon cycling and aggregate stability. They found that microplastics significantly altered soil aggregate size distribution and decreased organic carbon mineralization rates regardless of polymer type. The study suggests that microplastic contamination may slow the natural breakdown of organic carbon in agricultural soils by changing soil structure and microbial communities.
The Re-distribution of Pristine and Aged Microplastics (<50 µm) in Soil Aggregate Fractions
Researchers investigated how pristine and aged microplastics smaller than 50 micrometers redistribute among soil aggregate fractions during aggregation in two soil textures amended with organic matter, finding that aggregate formation actively partitions microplastics in ways influenced by soil texture and particle aging.
Adsorption of microplastic-derived organic matter onto minerals
Dissolved organic matter (DOM) released from weathered microplastics was studied for its adsorption onto soil minerals, a process relevant to microplastic fate and potential contaminant transport. Microplastic-derived DOM adsorbed onto mineral surfaces, altering soil chemistry and potentially stabilizing or mobilizing other contaminants in soil-water systems.
Research on the Effects of Aging Microplastics on Soil Nitrogen and Dissolved Organic Matter in Dryland Soil
Researchers examined the effects of aged microplastics at varying concentrations on nitrogen forms and dissolved organic matter (DOM) in dryland agricultural soil, finding that microplastic addition reduced ammonia nitrogen, nitrate nitrogen, and total nitrogen while altering DOM composition, humic content, and soil organic matter stability.
Microplastic effects on soil aggregation in sterilized and non-sterilized soils
Researchers tested how microplastics affect soil aggregate stability in both sterilized and non-sterilized soils, finding that microbial activity mediates much of the structural impact and that plastic type influences aggregation differently depending on soil biology.
Diverse Impacts of Microplastic-derived Dissolved Organic Matter at Environmentally Relevant Concentrations on Soil Dissolved Organic Matter Transformation
Researchers examined how dissolved organic matter leached from biodegradable and conventional agricultural mulch microplastics affects soil chemistry at environmentally realistic concentrations. They found that UV-exposed microplastic leachates were more bioavailable and caused greater changes to soil organic matter than those produced in dark conditions. The study suggests that even at low concentrations, microplastic-derived compounds can meaningfully alter soil carbon dynamics, with effects varying by soil type.
Molecular insights into effects of PBAT microplastics on latosol microbial diversity and DOM chemodiversity
Researchers found that biodegradable PBAT microplastics significantly altered soil microbial community diversity and dissolved organic matter composition in tropical latosol over 120 days, with effects intensifying at higher microplastic concentrations.
Dissolved organic matter leached from microplastic (MPs-DOM) divergently alters pyrene adsorption in soil
Dissolved organic matter leached from microplastics (MPs-DOM) was shown to alter microbial community structure and chemical cycling in water. This suggests that even without direct particle ingestion, the chemical leachates from plastics can reshape aquatic ecosystems.
Influence of microplastics on soil aggregate formation: Insights into biological binding agents
A laboratory experiment found that polyethylene microplastics in different shapes (granules, fibers, and films) and aging states significantly alter how soil particles clump together into aggregates, with effects depending on the plastic's shape and the soil's organic matter content. Disruption of soil aggregation by microplastics matters because aggregate structure controls water retention, aeration, and microbial habitat — all fundamental to healthy, productive soils.
Interactions between Microplastics and Dissolved Organic Matter in the Fresh Water Environment
This review explores how microplastics interact with dissolved organic matter (DOM) — the complex mixture of carbon compounds found in rivers and lakes — and what that means for freshwater ecosystems. Microplastics readily bind to DOM, altering its distribution in sediments and affecting the microbial communities that depend on it for food and energy. DOM can also change how far microplastics travel and how available they are to aquatic organisms. The interplay between these two classes of contaminant complicates efforts to predict microplastic behavior in the environment.
Microplastic effects on soil organic matter dynamics and bacterial communities under contrasting soil environments
Researchers compared microplastic effects on soil organic matter dynamics and bacterial communities across contrasting soil environments, finding that the type of microplastic polymer and soil conditions together determine whether microbial activity and carbon cycling are stimulated or suppressed.
Response of soil dissolved organic matter to microplastic addition in Chinese loess soil
Researchers added microplastics to loess soil at two concentrations and tracked dissolved organic matter over 30 days, finding that even moderate additions altered the rate of organic carbon, nitrogen, and phosphorus release, stimulated soil enzyme activity, and promoted accumulation of high-molecular-weight humic compounds — suggesting microplastic pollution reshapes soil nutrient cycling.
Inhibitory effect of microplastics on soil extracellular enzymatic activities by changing soil properties and direct adsorption: An investigation at the aggregate-fraction level
Researchers studied how polyethylene microplastics affect the activity of soil enzymes over 150 days, examining responses across different soil aggregate sizes. They found that microplastics inhibited enzyme activities by altering soil properties, directly adsorbing enzymes, and competing with microorganisms for space. The study reveals that microplastic pollution can undermine key biological processes that maintain soil quality, with different soil aggregate fractions responding in distinct ways.
Microplastics Trigger Soil Dissolved Organic Carbon and Nutrient Turnover by Strengthening Microbial Network Connectivity and Cross-Trophic Interactions
This study found that polyethylene and PVC microplastics in agricultural soil significantly altered the microbial communities responsible for breaking down organic carbon and recycling nutrients. The microplastics strengthened connections between bacteria, fungi, and other microorganisms in ways that accelerated carbon and nutrient turnover. These changes to fundamental soil processes could affect crop nutrition and long-term soil health on farms contaminated with microplastics.