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61,005 resultsShowing papers similar to Quantitative analysis of PBAT microplastics and their degradation products in soil by mass spectrometry
ClearDegradation of biodegradable plastic films in soil: microplastics formation and soil microbial community dynamics
Scientists tracked what happens when biodegradable PBAT plastic films break down in soil over 180 days and found they release microplastics that peaked before declining. Fungi broke the films into smaller pieces while bacteria consumed the fragments, suggesting that even plastics marketed as biodegradable generate microplastics during their breakdown, though soil microbes can eventually help clean them up.
The fate of post-use biodegradable PBAT-based mulch films buried in agricultural soil
Scientists tracked the breakdown of a biodegradable mulch film in farm soil over 16 months and found that while the film lost more than half its surface area, it released microplastics into the surrounding soil during the process. About 17-23% of the original film material was still recoverable from the soil after nearly 500 days. The study shows that even biodegradable plastics can be a source of microplastic contamination in agricultural soils.
Unravelling the ecological ramifications of biodegradable microplastics in soil environment: A systematic review
Researchers reviewed 85 studies on biodegradable microplastics in soil, finding that when biodegradable plastics fail to fully break down they can disrupt soil structure, nutrient cycling, and microbial life in ways that depend heavily on concentration and plastic type. The review highlights that "biodegradable" plastics are not a simple fix for microplastic pollution in agricultural soils.
Quantitative methodology for poly (butylene adipate-co-terephthalate) (PBAT) microplastic detection in soil and compost
Researchers developed a quantitative methodology for detecting poly(butylene adipate-co-terephthalate) (PBAT) microplastics in soil and compost matrices, addressing the need to monitor biodegradable mulch film fragmentation and mineralization in agricultural environments. The method enabled accurate measurement of PBAT microplastic concentrations across environmentally relevant matrices, providing a tool to assess the fate of biodegradable plastics in agroecosystems.
Unveiling the impact of biodegradable polylactic acid microplastics on meadow soil health
Scientists studied how biodegradable PLA microplastics affect meadow soil over 60 days and found they changed soil chemistry, enzyme activity, and microbial communities. Smaller PLA particles had a greater impact on enzyme activity, while larger particles changed soil properties more. These findings suggest that even biodegradable plastics can significantly alter soil health when they break down into microplastics.
Bioplastics in agricultural soils: Biodegradability, analytical techniques, and soil microbial impact
Researchers reviewed the evidence on how bioplastics degrade in agricultural soils, finding that commonly used analytical techniques overestimate biodegradation rates because they measure surface changes rather than full carbon mineralization, meaning biodegradable microplastic residues may persist across seasons under realistic conditions.
Quantitative methodology for poly (butylene adipate-co-terephthalate) (PBAT) microplastic detection in soil and compost
Researchers developed a GC-MS method using fatty acid methyl ester derivatization to quantify PBAT biodegradable microplastics in soil and compost, validated through an industrial composting experiment. The method tracked PBAT film mass loss and particle formation during degradation, providing a novel analytical tool for assessing biodegradable plastic fate in agricultural and composting environments.
[Degradation Processes of Biodegradable Plastics in Soil and Their Effects on Soil Animals].
Researchers reviewed the three-phase degradation process of biodegradable plastics in soil—biodeterioration, bio-depolymerization, and bioassimilation—and assessed how the resulting fragments and additives affect soil animals. They found that degradation byproducts and residual microplastics from biodegradable plastics can harm soil invertebrates, with effects depending on polymer type and soil conditions.
Improving analytical methods for the extraction and analysis of biodegradable and non-biodegradable microplastics in the soil environment.
Researchers worked to improve analytical extraction and detection methods for both biodegradable and conventional microplastics in soil environments, addressing a critical methodological gap given that terrestrial soils are major sinks for microplastic pollution entering through agricultural and waste management pathways.
Biodegradable plastics in the air and soil environment: Low degradation rate and high microplastics formation
Researchers compared the degradation rates of various biodegradable plastic types in natural air and soil environments over time, finding that most degraded slowly under ambient conditions and generated substantial microplastic fragments, with non-certified biodegradable plastics showing essentially no degradation.
A review on the occurrence and influence of biodegradable microplastics in soil ecosystems: Are biodegradable plastics substitute or threat?
This review examines whether biodegradable plastics are a genuine solution to plastic pollution or may create new problems in soil ecosystems. Researchers found that many biodegradable plastics do not fully break down under natural conditions and may actually fragment into microplastics faster than conventional plastics, potentially posing additional threats to soil health.
Microplastic accumulation in soils: Unlocking the mechanism and biodegradation pathway
Researchers reviewed how microplastics accumulate in soil and break down biologically, finding that certain microorganisms can form biofilms on plastic surfaces and use enzymes to slowly degrade the polymers — though conditions like pH, temperature, and moisture must be optimized and new plastic-degrading microbes need to be identified before this approach can be widely applied.
Microbial degradation of bioplastic (PHBV) is limited by nutrient availability at high microplastic loadings
Researchers found that the degradation of the biodegradable plastic PHBV in soil becomes limited by nutrient availability when microplastic concentrations are high. Using pyrolysis GC-MS to quantify degradation, they observed that soil hydrophobicity increased while plant growth and soil microbial biomass decreased at higher microplastic loadings. The study suggests that even biodegradable plastics can negatively affect soil health when present in large quantities.
Aging of biodegradable microplastics and their effect on soil properties: Control from soil water
Researchers studied how biodegradable microplastics made from PLA and PBAT break down in different soil types under varying water conditions. They found that while these plastics aged more in dry and alternating wet-dry conditions, flooded conditions caused bigger changes to soil chemistry, including increased dissolved organic carbon. The study suggests that even biodegradable plastics can meaningfully alter soil properties, and the effects depend heavily on moisture conditions.
A progress update on the biological effects of biodegradable microplastics on soil and ocean environment: A perfect substitute or new threat?
This review examines whether biodegradable plastics, often marketed as eco-friendly alternatives, actually break down safely in the environment. The evidence shows that biodegradable plastics often fragment into microplastics rather than fully decomposing, and these biodegradable microplastics can harm soil organisms, marine life, and disrupt nutrient cycles. The findings suggest that simply switching to biodegradable plastics may not solve the microplastic pollution problem and could introduce new environmental risks.
Addition of biodegradable microplastics alters the quantity and chemodiversity of dissolved organic matter in latosol
Researchers found that adding biodegradable PBAT microplastics to tropical soil increased microbial and enzyme activity, which in turn altered the quantity and chemical diversity of dissolved organic matter, suggesting biodegradable plastics still significantly affect soil biogeochemistry.
A review of biodegradation and formation of biodegradable microplastics in soil and freshwater environments
Researchers reviewed how biodegradable plastics break down in soil and freshwater, finding that incomplete degradation by microorganisms can still produce tiny biodegradable microplastic particles that persist in the environment — meaning "biodegradable" doesn't always mean safe or fast-disappearing.
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.
Novel insight into the in-situ study of biodegradable microplastics in soil aggregates
An in-situ study of biodegradable microplastic degradation under real environmental conditions revealed insights into how quickly these materials actually break down compared to lab predictions. The findings show that biodegradation rates in nature often differ significantly from those measured in controlled experiments.
A review of the occurrence and degradation of biodegradable microplastics in soil environments
This review evaluates whether the shift from conventional plastics to biodegradable plastics is truly beneficial for the environment, particularly regarding microplastic formation in soils. Researchers found that biodegradable plastics actually form residual microplastics at a faster rate than conventional plastics, and these particles can negatively affect soil properties, microbial communities, and plant growth. The study suggests the environmental trade-offs of biodegradable plastics deserve closer scrutiny.
Mineralization and microbial utilization of poly(lactic acid) microplastic in soil
Researchers tracked how polylactic acid (PLA) microplastics, a common biodegradable plastic, actually break down in different agricultural soils. They found that standard testing methods significantly overestimate how quickly PLA degrades because they fail to account for interactions with soil organic matter. The study reveals that PLA microplastics may persist longer in some soils than previously thought, raising questions about how truly biodegradable these materials are in real-world conditions.
Determining the impact of common microplastic extraction methods from soil matrices on the biodegradable polymers polylactic acid and polyhydroxybutyrate
Researchers tested whether standard lab methods used to extract microplastics from soil samples inadvertently degrade biodegradable plastics like polylactic acid (PLA) and polyhydroxybutyrate (PHB) before they can be measured. They found significant degradation, particularly of PLA when exposed to the enzyme protease, meaning common soil extraction protocols may undercount biodegradable plastic fragments and give a false impression of how completely these materials break down in nature.
Degradation of conventional, biodegradable and oxo-degradable microplastics in a soil using a d13C technique
Scientists tracked how four types of plastic — a conventional bag, two biodegradable plastics, and an oxo-degradable straw — break down in soil over 185 days using a carbon isotope technique. Even the most degradable plastic (a biodegradable bin liner) only mineralised 5.7% of its carbon, while conventional plastic bags barely degraded at 0.3%. Crucially, all plastics also triggered a 'priming effect' that accelerated the breakdown of existing soil organic carbon, meaning microplastics don't just persist — they alter the soil chemistry around them.
Aging Dynamics of Polyvinyl Chloride Microplastics in Three Soils with Different Properties
Researchers tracked how PVC microplastics age and degrade over 12 months in three different soil types. They found that soil properties significantly influenced the aging process, with sandy soil promoting more surface oxidation and silty clay causing greater physical fragmentation into smaller particles. The study reveals that microplastics do not remain static in soil but undergo continuous chemical and physical changes that may affect their environmental impact over time.