Microplastic biodegradability does not modify plant carbon input in soil but accelerate soil carbon loss in agroecosystems

土壤碳 环境科学 生物降解 土壤呼吸 土壤水分 农学 农业生态系统 环境化学 生态系统 化学 碳汇 土壤生物学 固碳 水槽(地理) 固碳 碳纤维 碳循环 土壤科学 光合作用 土壤有机质 土壤质地 微生物种群生物学 总有机碳 土壤退化 生态学 呼吸 大气碳循环 光合有效辐射 重氮
作者
Meng‐Ying Li,Wei Wang,Yudi M. Lozano,Yongxing Cui,Hong‐Yan Tao,Muhammad Ashraf,Matthias C. Rillig,You‐Cai Xiong
出处
期刊:Journal of Applied Ecology [Wiley]
卷期号:63 (1) 被引量:1
标识
DOI:10.1111/1365-2664.70259
摘要

Abstract Microplastics (MPs) are emerging contaminants that disrupt terrestrial carbon (C) cycling, yet how their biodegradability modulates the turnover of plant‐derived C remains unclear. Here, we investigated how two widely used MPs—non‐biodegradable polyethylene (PE) and biodegradable polylactic acid (PLA)—affected the fate of photosynthetically fixed C in a dryland agroecosystem. The goal was to explore how MPs influenced C fluxes across the soil–plant‐atmosphere continuum (SPAC) and assess their implications on climate change. We conducted a two‐year field experiment to evaluate how PE and PLA‐based MPs affected plant photosynthetic C fixation and its subsequent turnover in soil. Using 13 CO 2 pulse‐labelling, we traced the flow of photosynthetically fixed C across the SPAC under low, medium and high MP concentrations. We quantified: (i) 13 C distribution in plant shoots, roots and bulk soil; (ii) 13 C allocation among soil aggregate size fractions; and (iii) microbial EEAs, CAZy gene abundance and soil respiration dynamics. Soil C sink capacity tended to decline for both MPs types, as cumulative soil CO 2 emissions increased. On average, 13 C retained in soil decreased from 50.8 to 41.1 mg m −2 in MPs treatments, relative to the control. Interestingly, the underlying mechanisms differed among MP types. Non‐biodegradable PE‐MPs weakened soil aggregation and reduced 13 C retention in macroaggregates. However, biodegradable PLA‐MPs generated marginal effects on aggregation and enhanced the activity of microbial hydrolase, which negatively affected C retention. Moreover, metagenomics confirmed that PLA‐MPs enhanced microbial decomposition capacity by enriching C degradation and energy metabolism genes. Finally, photosynthetic C assimilation remained unchanged with increasing MP concentrations, regardless of MP types. Synthesis and applications . Both MP types can evidently impair soil C pools and differentially alter soil C cycling via the biodegradation‐dependent mechanisms. These findings challenge the widely held assumption that biodegradable MPs are inherently environmentally benign, as their presence in soils undermines C storage capacity. The findings offer insights into future applications as follows: (1) to phase down the increment and stock of soil MPs, in favour of truly green alternatives of plastic mulching; (2) to update the estimation methods of soil C emissions in global terrestrial ecosystems considering the presence of soil MPs.
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