Di-(2-ethylhexyl) phthalate (DEHP) contamination suppressed soil microbial biomass carbon and mitigated CO2 emissions against the background of alfalfa from different soils

Plastic mulching and organic amendments are prevalent agricultural practices worldwide. Plastic mulching has long been suspected as a significant source of DEHP contamination in terrestrial ecosystems. However, effects of DEHP contamination on greenhouse gas emissions and microbial biomass carbon (M...

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Published in:Ecotoxicology and environmental safety 2024-03, Vol.272, p.116073-116073, Article 116073
Main Authors: Shah, Jawad Ali, Ullah, Saif, Chen, Deyun, Wu, Jianping
Format: Article
Language:English
Subjects:
Alfalfa inclusion
Carbon dioxide emissions
Di-(2-ethylhexyl) phthalate
Microbial biomass carbon
Soil types
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Summary:Plastic mulching and organic amendments are prevalent agricultural practices worldwide. Plastic mulching has long been suspected as a significant source of DEHP contamination in terrestrial ecosystems. However, effects of DEHP contamination on greenhouse gas emissions and microbial biomass carbon (MBC) remain unclear. Here, a microcosm experiment was set up to assess the impact of DEHP exposure on MBC and carbon dioxide (CO2) emission in two different soils (acidic and alkaline) with the inclusion of alfalfa straw. The treatment includes: (i) control with no amendment (T1); (ii) alfalfa straw addition (20 g kg−1) (T2); (iii) DEHP (10 mg kg−1) + alfalfa straw (T3); and (iv) DEHP (100 mg kg−1) + alfalfa straw (T4). Against the background of alfalfa inclusion, DEHP exposure led to a potential reduction in cumulative CO2 emissions by 16.35 % and 6.91 % in alkaline soil and 12.27 % and 13.65 % in acidic soil for T3 and T4, respectively. The addition of DEHP triggered CO2 emissions and manifested a detrimental negative priming effect in both soil types. In both soils, average CO2 emission fluxes were highest for the T2 treatment. The MBC fluctuated at around 80 mg kg−1 for the control group, alfalfa straw alone (T2) treatment considerably enhanced MBC contents, whereas DEHP contamination in T3 and T4 treatments suppressed the stimulatory effect of alfalfa on MBC in both alkaline and acidic soils. Furthermore, a positive relationship was observed between soil CO2 emissions and MBC in both soils. Overall, these findings highlight the toxic impact of DEHP on MBC and its role in mitigating CO2 emissions in diverse soils. DEHP exposure counters the CO2 emissions induced by alfalfa straw. In addition, the inhibitory effect of DEHP on CO2 fluxes in alkaline soil is less pronounced than in acidic soil. Therefore, further cutting-edge research is crucial since DEHP contamination poses serious ecological threats to agroecosystems. [Display omitted] •DEHP exposure decreased CO2 emission fluxes.•DEHP manifested a detrimental impact on microbial biomass carbon.•MBC declined more strongly with lower concentrations of DEHP in acidic soil.•DEHP exposure mitigates the escalating CO2 emission induced by alfalfa straw.•The DEHP inhibitory effect on CO2 emission was lower in alkaline soil.
ISSN:0147-6513
1090-2414
DOI:10.1016/j.ecoenv.2024.116073