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61,005 resultsShowing papers similar to Novel insight into the in-situ study of biodegradable microplastics in soil aggregates
ClearBiodegradable 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 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.
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.
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.
The effect of biodegradable plastics on microplastic accumulation and exposure
Researchers developed a comprehensive method to quantify microplastic accumulation from biodegradable polymers in natural environments, examining whether biodegradable alternatives actually reduce plastic loads compared to conventional polymers under real-world outdoor conditions.
Microplastic incorporation into soil aggregates: Insights from two-year field experiments in European agricultural topsoils
Researchers conducted two-year field experiments in European agricultural topsoils comparing microplastic incorporation into soil aggregates from biodegradable and conventional plastic mulch films, finding that soil properties and MP size and shape influence the degree of occlusion, with aggregate embedment potentially protecting MPs from further degradation.
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.
Microplastic alteration in agricultural soils across Europe: Comparative study of MPs inside and outside soil aggregates over two years
Researchers tracked microplastic aging inside and outside soil aggregates in European agricultural soils over two years, comparing fields in multiple countries. Microplastics enclosed within aggregates showed less physicochemical aging than surface-exposed particles, suggesting that aggregate formation can temporarily protect plastics from degradation and prolong their persistence in soil.
Biodegradable Polyesters in Soil - Real Environmental Hazard or Just a Storm in a Teacup?
This review critically examines whether biodegradable polyesters genuinely degrade in soil environments, finding that under field conditions many degrade slowly and incompletely, forming persistent microplastic particles ('microbioplastics') with largely unknown ecological consequences.
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.
Degradation of Biodegradable Microplastics under Artificially Controlled Aging Conditions with UV Radiation
Researchers subjected biodegradable plastics to controlled UV aging and found that they fragmented into microplastics faster than conventional plastics under simulated outdoor conditions. Biodegradable plastics are promoted as an eco-friendly alternative, but this study shows they may actually create microplastic pollution more rapidly in real-world environments. The findings raise important questions about whether biodegradable plastics are a genuine solution to plastic pollution.
Review on the Biological Degradation of Polymers in Various Environments
This review provides an overview of how biodegradable plastics degrade under different environmental conditions including soil, freshwater, marine, and composting environments. It finds that biodegradability is a material property strongly dependent on environmental conditions, and that many so-called biodegradable plastics degrade far more slowly in nature than in controlled test 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.
Soil Properties as Key Determinants for the Biodegradation Kinetics of Polymer Blends in Indian Agroecosystems
Soil properties such as pH, texture, and organic matter content were identified as key determinants of how quickly biodegradable plastics break down in different soils. The findings explain why biodegradable plastics may persist much longer in some soils than expected based on manufacturer claims.
A state-of-the-art review of environmental behavior and potential risks of biodegradable microplastics in soil ecosystems: Comparison with conventional microplastics
This review compares the environmental behavior and risks of biodegradable microplastics with conventional microplastics in soil ecosystems. Researchers found that biodegradable microplastics fragment more readily and their abundant functional groups significantly affect how they transport and interact with other contaminants like heavy metals. The study suggests that biodegradable plastics may pose distinct and potentially underestimated risks to soil health compared to their conventional counterparts.
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.
Quantitative study of microplastic degradation in urban hydrosystems: Comparing in situ environmentally aged microplastics vs. artificially aged materials generated via accelerated photo-oxidation
Researchers compared how polyethylene microplastics degrade in real urban water environments versus under controlled laboratory UV exposure. They found that lab-aged plastics showed primarily physical and chemical changes from UV light, while microplastics collected from stormwater and sediments also showed signs of biological degradation and hydrolysis. The study demonstrates that artificial aging alone does not fully replicate the complex degradation processes microplastics undergo in actual urban water systems.
The association of microplastics with water-stable aggregates formed under controlled conditions
Researchers compiled data examining how microplastics associate with water-stable soil aggregates formed under controlled laboratory conditions, providing a dataset supporting the linked publication on microplastic-soil aggregate interactions.
The association of microplastics with water-stable aggregates formed under controlled conditions
Researchers compiled data from a controlled study examining the association between microplastics and water-stable soil aggregates, providing the underlying dataset for the linked publication on microplastic-aggregate interactions.
Degradation of Biodegradable Single-use Plates and Waste Bags in Terrestrial and Marine Environments
Field experiments found that biodegradable single-use plates and waste bags degraded at very different rates depending on material and environment, with some lasting far longer than expected. Products labeled as biodegradable may still persist and fragment into microplastics in natural marine and terrestrial conditions.
Investigating aquatic biodegradation and changes in the properties of pristine and UV-irradiated microplastics from conventional and biodegradable agricultural plastics
Researchers compared the biodegradation of conventional and biodegradable agricultural plastic mulching films in aquatic environments, testing both pristine and UV-weathered samples. The study found that while biodegradable plastics break down well under controlled composting conditions, their degradation in non-target environments like water bodies is considerably less predictable.
Insights into effects of conventional and biodegradable microplastics on organic carbon decomposition in different soil aggregates
Researchers compared how conventional polypropylene and biodegradable polylactic acid microplastics affect carbon decomposition in different sizes of soil aggregates. Both types of microplastics increased carbon dioxide emissions from soil, but the effects varied depending on particle type, concentration, and aggregate size. The study reveals that microplastics can alter soil carbon cycling at a fundamental structural level, with biodegradable plastics not necessarily being more benign than conventional ones.
In-soil degradation of polymer materials waste – A survey of different approaches in relation with environmental impact
This review surveys the in-soil degradation of polymer materials — including natural fibers, synthetic plastics, and composites — examining how environmental factors such as UV radiation, microorganisms, moisture, and temperature drive degradation and influence the environmental impact of plastic waste in terrestrial ecosystems.
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.