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61,005 resultsShowing papers similar to Synthesis of a new biocomposite for fertiliser coating: assessment of biodegradability and thermal stability
ClearSynthesis of a New Biocomposite for Fertiliser Coating: Assessment of Biodegradabilityand Thermal Stability
Researchers developed a biocomposite made from cellulose nanoparticles, natural rubber, and polylactic acid for use as a biodegradable fertilizer coating. Using natural biopolymers to coat fertilizers instead of conventional plastic films could help reduce agricultural microplastic contamination from plastic-coated slow-release fertilizers.
Development of Fertilizer Coatings from Polyglyoxylate–Polyester Blends Responsive to Root-Driven pH Change
Researchers developed biodegradable fertilizer coatings made from a self-degrading polymer blended with polycaprolactone or polylactic acid, designed to release nutrients in the acidic zone around plant roots. Replacing conventional non-biodegradable polymer coatings on fertilizers could significantly reduce microplastic accumulation in agricultural soils.
Deep insights into biodegradability mechanism and growth cycle adaptability of polylactic acid/hyperbranched cellulose nanocrystal composite mulch
Researchers developed biodegradable polylactic acid mulch films reinforced with hyperbranched cellulose nanocrystals, demonstrating tunable degradation rates under soil burial, seawater, and UV aging conditions alongside enhanced mechanical strength and crop yield — offering a viable petroleum-free alternative to conventional agricultural plastic mulch.
Functionalization of slow-release fertilizers and “passive predation microplastics” mechanism for polylactic acid composites
Researchers developed a biodegradable fertilizer film made from polylactic acid (PLA) and modified lignin that can slowly release nutrients while breaking down naturally in soil, offering an alternative to conventional plastic mulch. The study also explored how plants absorb tiny fragments of bio-based plastics, which is important for understanding whether even biodegradable alternatives still pose risks to food safety.
Advancements and challenges in controlled-release fertilisers: An approach to integrate biopolymer-based strategies
This review examines controlled-release fertilizers, which are designed to deliver nutrients to plants gradually, and finds that many use synthetic polymer coatings that can leave microplastic residues in soil. The authors highlight biopolymers made from natural materials like chitosan, cellulose, and starch as promising alternatives that can biodegrade without contributing to plastic pollution. The shift toward biodegradable fertilizer coatings could help reduce a significant but often overlooked source of agricultural microplastic contamination.
Aging of PLA/NR electrospun fibers under the influence of UV-irradiation, water and soil environment
Researchers tested how UV light, water, and soil exposure age and degrade biodegradable polylactic acid (PLA) and natural rubber (NR) composite fibers. Higher natural rubber content accelerated degradation, important information for designing biodegradable plastic products that break down as intended without generating persistent microplastics.
Cross-linked Cellulose Ester/Linseed Oil Composites for Controlled Release Fertilizers
Researchers developed cross-linked cellulose ester and linseed oil composites for use as controlled-release fertilizers, offering a biodegradable alternative to conventional plastic-coated fertilizers that shed microplastics into agricultural soils.
Unveiling the impact of soil depth on degradation of durable nanocomposite mulch-derived residue migration dynamics in plant ecosystems
Researchers studied how a self-degradable mulch film made from polylactic acid and hydrophobically modified nanocellulose behaves at different soil depths. The mulch increased soil moisture, promoted plant growth, and degraded faster than pure PLA, with degradation rate varying by soil depth. The study demonstrates that nanocomposite mulch films can reduce plastic pollution through effective biodegradation while supporting soil and plant health, though ecological risk assessments are recommended before large-scale use.
Design of Biodegradable PU Textile Coating
Researchers developed a biodegradable polyurethane coating for textiles as an alternative to conventional coatings that contribute to microplastic pollution when they end up in landfills. The new coating achieved nearly 60% biodegradation in soil while maintaining acceptable water barrier and mechanical properties. The study demonstrates that functional textile coatings can be designed to break down naturally, reducing their long-term environmental impact.
Fully bio-based polyurethane coating for environmentally friendly controlled release fertilizer: Construction, degradation mechanism and effect on plant growth
Researchers developed a fully bio-based polyurethane coating for controlled-release fertilizers using castor oil and a plant-derived chemical. Unlike conventional polyurethane coatings that persist in soil as microplastics, this coating showed strong biodegradability while still effectively controlling nutrient release. The study offers a practical solution to reduce microplastic accumulation in agricultural soils from fertilizer coatings.
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.
Plant stimuli-responsive biodegradable polymers for the use in timed release fertilizer coatings
This study developed plant-stimulated biodegradable polymer coatings for controlled-release fertilizers that break down when triggered by root secretions, releasing nutrients when plants need them. The innovation addresses the problem of conventional fertilizer coatings made from non-degradable polymers that contribute to microplastic contamination in agricultural soils.
Hydrolyzable microplastics in soil—low biodegradation but formation of a specific microbial habitat?
Hydrolyzable microplastics such as polylactic acid showed low biodegradation in soil despite their marketed degradability, while their surfaces hosted distinct microbial communities forming a specialized plastisphere. The study questions the environmental safety of biodegradable plastics in agricultural soil contexts.
Aging Process of Biocomposites with the PLA Matrix Modified with Different Types of Cellulose
Researchers prepared polylactic acid composites with three different cellulose-based fillers and studied how they age under UV light exposure. The study found that the type of cellulose additive plays a crucial role in how well the material resists UV degradation, with some forms improving both mechanical properties and degradation timing. These findings support the potential of biodegradable polymer composites as alternatives to conventional plastics that generate persistent microplastic waste.
Degradation of Polylactic Acid/Polypropylene Carbonate Films in Soil and Phosphate Buffer and Their Potential Usefulness in Agriculture and Agrochemistry
Researchers studied how blends of polylactic acid and polypropylene carbonate, two biodegradable plastics being promoted as eco-friendly alternatives, break down in soil and in laboratory conditions over time. The degradation was slow and incomplete, with the films losing weight and molecular structure gradually over 24 months. This raises concerns that even biodegradable plastics may persist in the environment long enough to fragment into microplastics before fully breaking down.
Influence of microbial biomass content on biodegradation and mechanical properties of poly(3-hydroxybutyrate) composites
This paper is not about microplastics — it studies how adding microbial biomass (algae and cyanobacteria) to a biodegradable polyester (PHB) accelerates its degradation rate in soil.
Long-term localization experiments reveal aging degradation mechanisms of biobased and petroleum-based polyurethanes in natural environments: degradation characteristics, product assessment and degradation cycle prediction
Researchers conducted a 807-day field localisation experiment to study the degradation mechanisms of biobased and petroleum-based polyurethanes used as polymer coatings on controlled-release fertilisers in natural soil environments. The study characterised the degradation products, assessed environmental risk, and developed a predictive model for the degradation cycle, finding that both polyurethane types fragment into microplastic residues at different rates.
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.
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 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.
Investigating the sustainability of agricultural plastic products, combined influence of polymer characteristics and environmental conditions on microplastics aging
Researchers investigated how polymer characteristics and environmental conditions influence the photodegradation of agricultural plastic products in soil. The study examined low-density polyethylene microplastic degradation under different UV radiation and humidity conditions. The findings suggest that environmental factors significantly affect how agricultural plastics break down into microplastics, with implications for understanding long-term soil contamination from farming practices.
Transformation of Polylactic Acid (PLA) Microparticles in Soil and their Effects on Soil Properties: A Review
This review examined how polylactic acid (PLA) microplastics transform in soil over time and affect soil physical, chemical, and biological properties including pH, organic matter, nutrient cycling, and microbial communities, highlighting the complexities of PLA as a supposedly biodegradable agricultural plastic.
Engineering biodegradable coatings for sustainable fertilisers
This review explored engineering biodegradable coatings for controlled-release fertilizers as sustainable alternatives to conventional plastic-coated products, addressing concerns about microplastic contamination from agricultural plastic films while maintaining effective nutrient delivery to crops.
On the quest for novel bio-degradable plastics for agricultural field mulching
This review examined the challenge of developing biodegradable plastic mulch materials suitable for agricultural use, noting that plasticulture consumes about 6.7 million tons of plastic annually, most of which cannot be practically recycled. The authors assessed candidate biodegradable polymers based on their degradation rates in soil, mechanical performance, and cost.