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Polyethylene microplastics distinctly affect soil microbial community and carbon and nitrogen cycling during plant litter decomposition

Journal of Environmental Management 2024 7 citations ? Citation count from OpenAlex, updated daily. May differ slightly from the publisher's own count. Score: 45 ? 0–100 AI score estimating relevance to the microplastics field. Papers below 30 are filtered from public browse.

Xianliang Yi, Wanxin Liu, Jiao Wang, Wanxin Liu, Xiaochen Chen, Chunbo Gu, Chunbo Gu, Jiao Wang, Jiao Wang, Xiaochen Chen, Jiao Wang, Xiaochen Chen, Bushra Maryam, Xianhua Liu Jiao Wang, Xianliang Yi, Bushra Maryam, Chunbo Gu, Chunbo Gu, Xianhua Liu Wanxin Liu, Xianliang Yi, Xianliang Yi, Xianhua Liu Xianhua Liu Xianliang Yi, Xianhua Liu Chunbo Gu, Xianliang Yi, Chunbo Gu, Yi Wang, Xiaochen Chen, Xiaochen Chen, Wanxin Liu, Jiao Wang, Jiao Wang, Yexin Dai, Yexin Dai, Chunbo Gu, Xianhua Liu Bushra Maryam, Bushra Maryam, Bushra Maryam, Jiao Wang, Xianhua Liu Jiao Wang, Chunbo Gu, Yexin Dai, Jiao Wang, Xianhua Liu Xianhua Liu Xianliang Yi, Jiao Wang, Jiao Wang, Wanxin Liu, Wanxin Liu, Xiaochen Chen, Xiaochen Chen, Yexin Dai, Bushra Maryam, Xianhua Liu Bushra Maryam, Xianhua Liu Xianhua Liu Jiao Wang, Xianhua Liu Xianhua Liu Xiaochen Chen, Xianliang Yi, Xianliang Yi, Xianhua Liu Yexin Dai, Xianhua Liu Xianhua Liu Xianhua Liu Jiao Wang, Xianliang Yi, Bushra Maryam, Xianhua Liu Xiaochen Chen, Xianhua Liu Bushra Maryam, Xianhua Liu Xianliang Yi, Xianhua Liu Bushra Maryam, Xianhua Liu Xianhua Liu Xianhua Liu Xianhua Liu Xianliang Yi, Xianliang Yi, Xianliang Yi, Xianliang Yi, Xiaochen Chen, Xiaochen Chen, Xianliang Yi, Xianhua Liu Xianhua Liu Xiaochen Chen, Xianhua Liu Xiaochen Chen, Xianhua Liu Xianhua Liu Xianhua Liu Xianhua Liu Xianliang Yi, Xianhua Liu Xianliang Yi, Xianliang Yi, Xianliang Yi, Xianhua Liu Xianhua Liu Xianhua Liu Xianhua Liu Xianhua Liu Xianhua Liu Xianhua Liu Xianhua Liu Xianhua Liu Xianhua Liu Xianhua Liu Xianhua Liu Xianhua Liu

Summary

Researchers measured how polyethylene microplastics affect soil microbial communities and carbon cycling in agricultural soils, finding that microplastic addition shifted microbial diversity and suppressed key carbon mineralization processes. The results suggest microplastic accumulation in farmland could impair soil carbon storage.

Polymers

Plant litter is an important input source of carbon and nitrogen in soil. While microplastics (MPs) and plant litter are ubiquitously present in soil, their combined impact on soil biogeochemical processes remains poorly understood. To address this gap, we examined the soil changes resulting from the coexistence of plant litter (Alfalfa) and polyethylene microplastics (PE). The soil changes included physicochemical properties, composition of soil dissolved organic matter, and structure of the soil microbial community. The results showed that the addition of polyethylene (PE) inhibited the degradation of humus-like substances and decreased the quantity of humic acid-like compounds in soil dissolved organic matter (DOM). PE negatively impacted plant litter decomposition, disrupted soil organic carbon (SOC) breakdown, interfered with the nitrogen cycle, and significantly altered microbial community structures during the process. By day 35, SOC and total nitrogen (TN) levels were reduced by 39.8% and 10.1%, respectively, in the presence of PE. Furthermore, PE significantly decreased the abundance of nitrogen-fixing microbes, including Streptomyces (43.1%) and Bacillus (45.9%), which play key roles in nitrate reduction to ammonium. This study highlights the environmental effects of MPs on plant litter decomposition and their potential implications for soil biogeochemical processes.

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