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61,005 resultsShowing papers similar to Effects of microplastics on carbon release and microbial community in mangrove soil systems
ClearDepth-dependent response of soil microbial community and greenhouse gas efflux to polylactic acid microplastics and tidal cycles in a mangrove ecosystem
Researchers found that biodegradable plastic (PLA) microplastics in mangrove soil increased the release of greenhouse gases, especially carbon dioxide and methane, from deeper soil layers. The microplastics altered soil bacterial communities in ways that boosted methane-producing organisms. This finding is important because biodegradable plastics are often marketed as environmentally friendly, but they may still harm ecosystems by accelerating carbon release from soils.
Effects of polypropylene microplastics on carbon dioxide dynamics in intertidal mangrove sediments
This study investigated how polypropylene microplastics affect carbon dioxide dynamics in mangrove sediments. Researchers found that microplastic contamination altered organic carbon content and microbial communities, influencing CO2 release patterns differently depending on tidal elevation and microplastic concentration.
Microplastic pollution threatens mangrove carbon sequestration capacity
Researchers found that microplastic pollution in mangrove soils is linked to increased methane production potential by favoring methane-producing archaea over methane-consuming bacteria. A nationwide survey of Chinese mangroves revealed higher microplastic concentrations in surface soils, with stronger associations with methane-cycling microorganisms at shallow depths. The findings suggest that plastic pollution could undermine the carbon sequestration capacity of these critical coastal ecosystems, potentially turning them from carbon sinks into greenhouse gas sources.
Coupling of sulfate reduction and dissolved organic carbon degradation accelerated by microplastics in blue carbon ecosystems
Researchers found that polylactic acid (PLA) microplastics in mangrove sediments accelerated the breakdown of dissolved organic carbon by boosting sulfate-reducing bacteria activity. Millimeter-sized PLA particles had a greater effect than micrometer-sized ones, fundamentally altering carbon and sulfur cycling in these important coastal ecosystems. This matters because mangrove sediments are major carbon stores, and microplastic contamination could speed up carbon release, worsening climate change.
Effect of microplastics on CO2 emission from Yellow River Delta wetland
Researchers found that microplastic contamination in Yellow River Delta wetland soils altered CO2 emissions, with different polymer types and concentrations producing varying effects on soil carbon dynamics — raising concern that plastic pollution could undermine the carbon sequestration function of coastal wetlands.
Differential carbon accumulation of microbial necromass and plant lignin by pollution of polyethylene and polylactic acid microplastics in soil
This study found that both conventional polyethylene and biodegradable polylactic acid microplastics changed how carbon is stored in soil. The plastics increased carbon from dead microbes while decreasing carbon from plant material, with most of the additional soil carbon coming from fungal remains. These changes to soil chemistry matter because they could affect agricultural productivity and the ability of soil to store carbon, with broader implications for climate and food systems.
Effects of Microplastics on Soil Carbon Mineralization: The Crucial Role of Oxygen Dynamics and Electron Transfer
Researchers investigated how polyethylene and polylactic acid microplastics affect carbon cycling in soil, focusing on oxygen dynamics and electron transfer processes. They found that microplastics alter dissolved oxygen distribution at the microscale, which in turn influences how organic matter breaks down and whether carbon is released as CO2 or methane. The study reveals a previously overlooked mechanism by which microplastics can disrupt fundamental soil carbon processes.
A review on microplastic pollution in the mangrove wetlands and microbial strategies for its remediation
Researchers reviewed the growing problem of microplastic pollution in mangrove wetland ecosystems and its effects on the biological communities that depend on these habitats. They found that microplastic exposure can substantially alter the microbial communities critical to nutrient cycling in mangrove environments. The review also explores microbial bioremediation strategies as a sustainable approach to addressing plastic pollution in these threatened coastal ecosystems.
Microbial colonization and succession on polylactic acid microplastics (PLA MPs) in mangrove forests - the role of environmental conditions and plastic properties
Researchers incubated two types of biodegradable polylactic acid microplastics in mangrove ecosystems across four environmental settings for 90 days to study microbial colonization patterns. They found that microbial colonization progressed more rapidly in sediment than in water, and the type of plastic influenced which microbial communities developed. The study suggests that environmental conditions and plastic properties together shape how microorganisms interact with biodegradable plastics in natural settings.
Subtle biogeochemical consequences of biodegradable and conventional microplastics in estuarine blue carbon systems
Researchers conducted field experiments exposing mangrove ecosystems to conventional and biodegradable microplastics for up to 100 days. While overall microbial community composition remained stable, the biodegradable microplastics temporarily disrupted key nutrient cycling processes for carbon, nitrogen, and phosphorus. The findings suggest that even in resilient blue carbon ecosystems, biodegradable plastics can cause subtle but measurable changes to biogeochemical functions.
Vegetation, salinity, and tides drive nitrogen cycling in Mangrove plastispheres
Researchers studied how microplastics affect nitrogen-cycling microbial communities in mangrove ecosystems under varying salinity and tidal conditions. They found that microplastic surfaces hosted distinct microbial communities with significantly higher abundances of nitrogen-cycling genes compared to surrounding soils. The study suggests that microplastics may act as hotspots for nitrogen transformation in mangrove environments, potentially disrupting natural nutrient cycling.
Microplastics and heavy metals reshape mangrove rhizosphere microbiomes and compromise carbon fixation potential
Researchers investigated how microplastics and heavy metals together affect the microbial communities around mangrove tree roots. They found that combined pollution significantly reduced microbial diversity and shifted the balance of bacterial species, which in turn compromised the ability of these ecosystems to capture and store carbon. The study highlights that microplastic-metal co-contamination poses a compounding threat to mangrove ecosystems, which play an important role in coastal carbon storage.
Disentangling microplastics effects on soil structure, microbial activity and greenhouse gas emissions
Researchers studied how microplastics affect soil structure, microbial activity, and greenhouse gas emissions, finding complex interactions that depend on microplastic type and concentration. The presence of microplastics in soils can alter the biological processes that regulate carbon storage and nutrient cycling.
Mangrove degradation retarded microplastics weathering and affected metabolic activities of microplastics-associated microbes
Microplastic weathering was slower in degraded mangrove sediments than in intact mangroves, with degradation also altering the composition and metabolic activity of microplastic-associated microbial communities. The findings suggest mangrove ecosystem health influences how rapidly microplastics degrade and what ecological roles microplastic-associated microbes play in these coastal environments.
Distribution characteristics of microplastics in the soil of mangrove restoration wetland and the effects of microplastics on soil characteristics
Researchers measured microplastic distribution in soils of a mangrove restoration wetland with different planting densities, finding an average abundance of 217 MPs per kilogram of dry soil with higher concentrations in denser planting zones. MPs in the soil also altered wetland soil physicochemical properties including bulk density and organic matter content.
Polyethylene microplastics distinctly affect soil microbial community and carbon and nitrogen cycling during plant litter decomposition
Researchers measured how polyethylene microplastics affect soil microbial communities and carbon cycling in agricultural soils, finding that microplastic addition shifted microbial diversity and suppressed key carbon mineralization processes. The results suggest microplastic accumulation in farmland could impair soil carbon storage.
The combined effects of microplastics and their additives on mangrove system: From the sinks to the sources of carbon
This review examined how microplastics and plastic additives (including flame retardants and phthalate plasticizers) affect carbon sequestration in mangrove blue carbon ecosystems, finding that MPs can shift mangroves from carbon sinks to potential carbon sources by disrupting soil organic carbon storage and microbial decomposition.
Microplastic effects on carbon cycling processes in soils
Researchers reviewed how microplastics affect carbon cycling processes in soils, including their influence on microbial activity, plant growth, and litter decomposition. Since microplastics are themselves carbon-based materials, they can directly alter soil carbon stocks while also indirectly shifting microbial communities. The study calls for a major research effort to understand the widespread effects of microplastics on soil functioning and terrestrial ecosystem health.
Effects of Microplastics on Microbial Community in Zhanjiang Mangrove Sediments
Researchers found that microplastics in mangrove sediments from Zhanjiang, China, altered the diversity and composition of microbial communities and may affect nitrogen cycling processes such as nitrification.
Colonization characteristics and dynamic transition of archaea communities on polyethylene and polypropylene microplastics in the sediments of mangrove ecosystems
Researchers found that microplastics in mangrove sediments host distinct communities of archaea (ancient microorganisms) that differ from those in surrounding sediments, with some species linked to increased methane production. The microbial communities on microplastic surfaces shifted over time and showed increased potential for methane emissions and changes in nitrogen cycling. This suggests that microplastic pollution in coastal wetlands could amplify greenhouse gas production and disrupt nutrient cycles that support these critical ecosystems.
Influence of biodegradable microplastics on soil carbon cycling: Insights from soil respiration, enzyme activity, carbon use efficiency and microbial community
Researchers investigated how biodegradable microplastics affect carbon cycling in soil by measuring respiration, enzyme activity, and microbial communities over 64 days. They found that certain biodegradable plastics, particularly polyhydroxyalkanoates, dramatically increased soil carbon emissions by up to 665% and significantly altered microbial community structure. The study suggests that even biodegradable plastics can substantially disrupt soil ecosystem processes when they break down into microplastic-sized particles.
Microplastics strengthen nitrogen retention by intensifying nitrogen limitation in mangrove ecosystem sediments
In a lab experiment simulating mangrove wetland sediments, microplastics altered nutrient cycling by intensifying nitrogen limitation, which changed how microbes processed nitrogen. While focused on environmental impacts, this matters because mangrove ecosystems are important coastal filters, and disrupting their nutrient cycles could affect downstream water quality and the health of seafood that humans consume.
Microplastic-Derived Dissolved Organic Matter Regulates Soil Carbon Respiration via Microbial Ecophysiological Controls
Researchers investigated how dissolved organic matter released by microplastics affects the way soil microbes process carbon. They found that compounds leaching from both new and aged microplastics stimulated soil carbon release, with aged microplastics having a larger effect by altering microbial community structure. The findings suggest that microplastic pollution may influence soil carbon cycling and potentially affect how effectively soils store carbon.
Widespread microplastic pollution in mangrove soils of Todos os Santos Bay, northern Brazil
Researchers found widespread microplastic pollution in mangrove soils around Todos os Santos Bay in Brazil, detecting contamination at multiple depths and distances from the tidal area, highlighting mangroves as previously overlooked sinks for microplastic accumulation.