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61,005 resultsShowing papers similar to Stabilized Sewage Sludge as Fertilizer: Risks Related to the Presence of Microplastics
ClearAssessment of the Presence of Microplastics in Stabilized Sewage Sludge: Analysis Methods and Environmental Impact
Researchers measured microplastic levels in treated sewage sludge used to make agricultural fertilizer and found concentrations as high as 2,942 fragments per 100 grams of dry material. Low-density polyethylene fragments were the most common type detected, with the highest levels occurring during summer months. When this sludge-based fertilizer is applied to farmland, it could introduce thousands of microplastic particles per square meter of soil, raising concerns about long-term soil health.
Microplastic contamination in sewage sludge: Abundance, characteristics, and impacts on the environment and human health
This review focuses on microplastics found in sewage sludge, which is often spread on agricultural land as fertilizer. The practice introduces microplastics directly into farm soil, where they can be taken up by crops or leach into groundwater. This creates a pathway for microplastics to reach human food and drinking water, raising concerns about the safety of using sewage sludge in agriculture.
Hidden contaminants: Unveiling the content of microplastics in municipal sewage sludge that may affect soil ecosystems
Researchers analyzed sewage sludge from two municipal treatment plants and found up to 116,000 microplastic particles per kilogram of dry sludge, with fiber-shaped and film-shaped particles dominating each plant respectively — highlighting the risk of spreading microplastic contamination to farmland when sludge is used as fertilizer.
An Overlooked Entry Pathway of Microplastics into Agricultural Soils from Application of Sludge-Based Fertilizers
Researchers analyzed sludge-based fertilizers applied to agricultural soils and found high microplastic concentrations (hundreds to thousands per kilogram of dry weight) that were transferred to soils after application, identifying this as an important but overlooked pathway for terrestrial microplastic contamination.
Agricultural application of microplastic-rich sewage sludge leads to further uncontrolled contamination
Researchers found that 44% of microplastics from sewage sludge applied to agricultural land migrated to nearby untreated areas, demonstrating that this common fertilizer practice leads to further uncontrolled contamination of surrounding soils.
Microplastics in sewage sludge from the wastewater treatment plants in China
Researchers analyzed microplastics in sewage sludge from wastewater treatment plants across China, finding high concentrations of microplastics — predominantly fibers and fragments — raising concerns about their spread when sludge is applied to agricultural land.
Microplastics in Sludges and Soils: A Comprehensive Review on Distribution, Characteristics, and Effects
This review summarizes research on microplastics in sewage sludge and soil, noting that when contaminated sludge is used as fertilizer, it turns farmland into a major reservoir for microplastic pollution. The accumulated microplastics can alter soil properties, harm soil organisms, and potentially enter crops and groundwater, creating pathways for human exposure through food and drinking water.
Microplastics in Sewage Sludge: A review
This review examines the presence and fate of microplastics in sewage sludge from municipal wastewater treatment plants, a topic that has received less attention than microplastics in the water treatment line. The study highlights that agricultural application of sewage sludge is a primary source of microplastic contamination in soils, and provides a comprehensive overview of detection methods, concentrations, and the environmental implications of sludge-borne microplastics.
Risk of re-release of microplastics from sewage fertilisers into the environment
This paper reviews the risk that microplastics in sewage sludge (biosolids used as agricultural fertilizer) will be re-released into soils and water when the sludge is land-applied. Microplastics from cosmetics and clothing fibers concentrate in sludge during wastewater treatment and persist because they resist biodegradation. Applying microplastic-contaminated biosolids to farmland is one of the major pathways through which microplastics enter agricultural soils.
Mapping microplastics in sludge
Researchers mapped microplastic contamination in sewage sludge from eight Norwegian wastewater treatment plants, finding plastics in all ten samples with an overall average of 6,077 particles per kilogram dry weight. Based on current sludge application rates in Norway, researchers estimated that over 500 billion microplastic particles enter the environment annually through agricultural and land application of sewage sludge.
Sewage sludge application as a vehicle for microplastics in eastern Spanish agricultural soils
Scientists measured microplastics in sewage sludge from Spanish wastewater treatment plants and in agricultural soils receiving sludge applications, finding that sludge application transferred hundreds to thousands of microplastic particles per kilogram into agricultural soil.
Microplastics in an agricultural soil following repeated application of three types of sewage sludge: A field study
Researchers investigated microplastics in agricultural soil after repeated sewage sludge application, finding that sludge-amended soils contained significantly more small microplastic particles than unamended soils, with particle accumulation varying by sludge type.
Fate of microplastics in sewage sludge and in agricultural soils
Researchers reviewed how microplastics accumulate in sewage sludge at wastewater treatment plants and then spread into agricultural soils when that sludge is applied as fertilizer, finding that sludge treatment processes can alter microplastic size and shape but do not eliminate them. The review calls for standardized methods to study how different sludge treatments affect microplastic properties and their downstream risks to soil health.
Tracking nonregulated micropollutants in sewage sludge: Antimicrobials, OH-PAHs, and microplastics — Environmental risks, fertilizer implications and energy considerations
Researchers tracked antimicrobials, hydroxylated polycyclic aromatic hydrocarbons, and microplastics in sewage sludge and fertilizers derived from it. The study found that while fertilizer production reduced some contaminants, significant levels of antimicrobials and an average of over 2,400 microplastic particles persisted in stabilized sludge, raising concerns about environmental contamination when these materials are applied to agricultural land.
Microplastics in Sewage Sludge: A Known but Underrated Pathway in Wastewater Treatment Plants
This review finds that wastewater treatment plants effectively transfer microplastics from effluent into sewage sludge, creating a significant but underrated pathway for MP contamination when sludge is applied to agricultural soils.
Impact of sewage sludge application on soil microplastic accumulation and nutrient levels: Analysis of 22 years of data from central UK farmland
Researchers analyzed a 22-year dataset from 5,323 fields in central UK to examine the relationship between repeated sewage sludge application and microplastic accumulation in agricultural soils, alongside changes in nutrient levels such as nitrogen and phosphorus. They found that microplastic concentrations increased with cumulative sludge applications while nutrients were taken up by crops, raising concerns about long-term plastic accumulation in farmland receiving sludge-derived fertilizers.
The overlooked pathway: A systematic review on sewage sludge treatment as a critical secondary source of terrestrial micro(nano)plastics
This systematic review examines sewage sludge as an overlooked pathway for microplastics to contaminate land, with concentrations reaching over 1,300 particles per kilogram. When this sludge is applied to farmland as fertilizer, aged and chemically modified microplastics enter agricultural soil, where they may be more toxic than fresh particles and can potentially be taken up by crops.
Evidence of microplastic accumulation in agricultural soils from sewage sludge disposal
Agricultural soils from 31 fields with different sludge application histories were analyzed for microplastics, finding significant accumulation in fields with repeated sludge applications and a positive correlation between application frequency and plastic particle counts. The study provides direct field evidence that sewage sludge fertilization is a major pathway for microplastic accumulation in agricultural soil.
Sewage Sludge-Mediated Microplastic Transfer to Agroecosystem: A Comprehensive Review on Detection, Fate and Ecological Impacts
This review study shows that tiny plastic particles called microplastics are getting into farm soil through sewage sludge that's used as fertilizer. When wastewater treatment plants process our sewage, they capture these plastic bits in the leftover sludge, which farmers then spread on their fields. This matters because these microplastics could potentially affect our food supply and soil health, but scientists still need more research to understand the full risks.
Sewage Sludge in Farmlands: A Gateway to Soil Microplastic Pollution?
Researchers analysed microplastic contamination in dewatered anaerobically digested sewage sludge and adjacent agricultural fields in the UK with varied sludge application histories, using fluorescence microscopy and FTIR/Raman spectroscopy to detect predominantly polyethylene, polyester, polypropylene, polystyrene, PVC, and polyamide particles.
Investigation and analysis of microplastics in sewage sludge and biosolids: A case study from one wastewater treatment works in the UK
Researchers investigated microplastic contamination in sewage sludge and biosolids at a UK wastewater treatment plant and found significant quantities of microplastics persisting through the treatment process. Since millions of tonnes of biosolids are applied to farmland annually in the UK, this represents a major pathway for microplastic pollution entering agricultural soils. The study highlights the need for better monitoring and treatment methods to reduce microplastic transfer from wastewater to the terrestrial environment.
A Quantitative Environmental Risk Assessment for Microplastics in Sewage Sludge Applied to Land
Researchers conducted a quantitative risk assessment of microplastics in sewage sludge applied to farmland and found that contamination levels frequently exceed safe thresholds for soil organisms. Even under realistic scenarios, the microplastic concentrations in sludge-amended soils were estimated to affect 15 to 18 percent of soil species. The study suggests that regulatory limits on microplastics in agricultural sludge should be urgently considered to protect soil ecosystems.
Configuration-driven microplastic fate in full-scale sewage sludge treatment and opportunities for system-level mitigation
Researchers examined how different treatment configurations in wastewater plants shape the types and concentrations of microplastics that end up in sewage sludge — the solid byproduct that is frequently spread on agricultural land as fertilizer. Microplastic concentrations in final sludge ranged from 617 to 936 particles per gram of dry solids, with fine fragments under 100 micrometers dominating, and the specific sequence of thickening, digestion, and dewatering steps significantly influenced which polymer types were retained. Since sludge application is a major route for microplastics to enter farmland, optimizing treatment processes could meaningfully reduce environmental contamination.
Source, occurrence, migration and potential environmental risk of microplastics in sewage sludge and during sludge amendment to soil
This review examines microplastics in sewage sludge and the risks of applying sludge as agricultural fertilizer, finding that sludge acts as both a sink for sewage microplastics and a source when spread on fields. Co-accumulated heavy metals, antibiotics, and antibiotic resistance genes on microplastics further complicate the environmental risks of sludge amendment to soils.