We can't find the internet
Attempting to reconnect
Something went wrong!
Hang in there while we get back on track
[Effects of Microplastics on Soil N2O Emission and Nitrogen Transformations from Tropical Agricultural Soils].
Summary
Researchers conducted a controlled laboratory incubation experiment to examine the effects of polyethylene and polybutylene adipate co-terephthalate microplastics on N2O emissions and nitrogen transformations in tropical agricultural soils from a pepper-corn cropping system in Hainan Province, China.
A widespread concern had been there regarding soil ecological and environmental problems caused by microplastic pollution in agricultural soils. A controlled laboratory incubation experiment was performed to examine the effects of different types of microplastics on soil properties, N2O emissions, and nitrogen (N) transformations in tropical arable soils from a pepper-corn cropping system in Hainan Province. Three treatments were done: soil without microplastics (CK) and soil amended with 5% of polyethylene (PE) or with 5% of polybutylene adipate co-terephthalate (PBAT). The results showed that both types of microplastic addition increased soil pH, soil organic carbon (SOC), and dissolved organic carbon (DOC) contents, with stronger treatment effects observed for PBAT than those for the PE treatment. In addition, the PE and PBAT treatments increased soil ammonium nitrogen (NH4+-N) contents by 66.07% and 119.65% and decreased nitrate nitrogen (NO3--N) contents by 8.56% and 29.68%, respectively. Compared to those in the CK treatment, the addition of PBAT significantly increased soil N2O emissions by 254.92% (P < 0.05), whereas that of PE produced no significant effects. Furthermore, both the PE and PBAT treatments increased soil net nitrogen mineralization rate (NMR) and decreased soil net nitrification rate (NNR), with more obvious treatment effects observed in PBAT than in the PE treatment. PBAT addition increased the abundance of ureC, while PE had no significant effects. Microplastic addition reduced the abundance of nitrifying gene abundances (AOA-amoA, AOB-amoA, and nxrA), with more obvious treatment effects found in the PBAT treatment. Further, PBAT addition significantly increased the gene abundances of nirK, nirS, nosZ, and fungal nirK (P < 0.05), whereas the addition of PE had no significant effect on those gene abundances. Soil N2O emissions had positive relationships with NH4+-N intensity, pH, DOC, SOC, and nirS abundance. In conclusion, biodegradable microplastics addition produced stronger influences on soil properties and N transformations than the non-biodegradable one in tropical arable soils and aggravated soil N2O emissions mainly by promoting denitrification.
Sign in to start a discussion.
More Papers Like This
[Advances in the Effects of Microplastics on Soil N2O Emissions and Nitrogen Transformation].
This review synthesizes current research on how microplastics affect soil nitrogen cycling, including N2O emissions, nitrogen transformation processes, functional enzyme activity, and nitrogen-related genes, highlighting inconsistent findings due to variability in microplastic properties, experimental conditions, and spatial-temporal scales.
Effects of microplastics on N2O production and reduction potential in crop soils of northern China
This study examined how polyethylene and polypropylene microplastics at concentrations of 0.5 to 3% affect nitrous oxide production and reduction potential in crop soils from northern China. Results showed that microplastic contamination altered N2O fluxes in vegetable soils by disrupting denitrification pathways, with implications for agricultural greenhouse gas emissions.
[Advances in Research of the Effects and Mechanisms of Polyethylene Microplastics on Soil Nitrogen Transformation].
This review examines the effects and mechanisms by which polyethylene microplastics — the dominant microplastic type in Chinese agricultural soils — influence elemental cycling processes in soil, summarizing findings on carbon, nitrogen, and phosphorus dynamics under microplastic exposure.
Effects of microplastics on soil organic carbon and greenhouse gas emissions in the context of straw incorporation: A comparison with different types of soil
Researchers combined microplastic treatments with straw incorporation in different soil types and measured effects on soil organic carbon and greenhouse gas emissions, finding that microplastics altered carbon cycling and in some soils increased CO2 and N2O emissions.
Soil Greenhouse Gas Emissions and Nitrogen Dynamics: Effects of Maize Straw Incorporation Under Contrasting Nitrogen Fertilization Levels
Not relevant to microplastics — this study examines how maize straw incorporation into soils with different nitrogen fertilization histories affects greenhouse gas emissions and nitrogen cycling in agricultural fields.