Effects of microplastics polluted soil on the growth of Solanum lycopersicum L.

Environmental Systems Research Pub Date : 2024-08-31 DOI:10.1186/s40068-024-00367-2

Era Juliet Das, A. K. M. Rashidul Alam

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Abstract

This study employed two prevalent plastic products - straws and microfiber as microplastics (MPs) to elucidate their largely unexplored effects on soil’s properties and the growth of the tomato plant (Solanum lycopersicum L.). For this experiment, a completely randomized design (CRD) was adopted where, straw - polypropylene (PP), microfiber - polyester (PES) + polyamide (PA), and their combinations (PP + PES + PA) were mixed with soil using different concentrations – 0% (control), 0.4%, 1%, and 2% (treatments) and kept for 45 days at room temperature. The findings demonstrated that incorporating 2% mixed MPs in soil significantly decreased bulk density and electrical conductivity 7.29% and 67.3%, respectively, while soil pH increased 17.84% in cultures containing 1% microfiber. Maximum water holding capacity (MWHC), soil organic carbon (SOC), and soil organic matter (SOM) showed varied responses based on MPs type and concentration. Specifically, MWHC increased 16.4% with 2% microfiber but declined 13.3% with 0.4% straw. The highest decreased (30.65%) in SOC and SOM were evident in cultures with 1% microfiber whereas increased 9.68% and 8.33% in cultures with 0.4% straw. In terms of the growth traits of S. lycopersicum, substantial reductions in plant height (56.37%), leaf number (54.37%), and girth diameter (56.43%) were observed in 2% straw containing cultures. Although no plant mortality was noted, the most pronounced reductions in leaf area (62.44%) and total plant biomass (68.16%) occurred in 2% microfiber cultures. Therefore, the ramifications of these findings may contribute to a deeper comprehension of the mechanisms and effects of MPs on soil properties and above-ground plant growth.

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微塑料污染土壤对番茄茄属植物生长的影响

本研究采用了两种常见的塑料产品--秸秆和超细纤维作为微塑料（MPs），以阐明它们对土壤性质和番茄（Solanum lycopersicum L.）生长的影响。该实验采用了完全随机设计（CRD），将稻草-聚丙烯（PP）、超细纤维-聚酯（PES）+聚酰胺（PA）以及它们的组合（PP + PES + PA）与土壤混合，使用不同的浓度--0%（对照）、0.4%、1% 和 2%（处理），并在室温下保持 45 天。研究结果表明，在土壤中加入 2% 的混合 MPs 会显著降低容重和导电率，降幅分别为 7.29% 和 67.3%，而在含有 1% 超细纤维的培养物中，土壤 pH 值提高了 17.84%。最大持水量（MWHC）、土壤有机碳（SOC）和土壤有机质（SOM）因 MPs 类型和浓度的不同而表现出不同的反应。具体来说，2% 的超细纤维使最大持水量增加了 16.4%，而 0.4% 的稻草使最大持水量减少了 13.3%。在使用 1%超细纤维的培养物中，SOC 和 SOM 的降幅最大（30.65%），而在使用 0.4% 稻草的培养物中，SOC 和 SOM 的降幅分别为 9.68% 和 8.33%。就番茄的生长特性而言，在含有 2% 稻草的培养物中观察到植株高度（56.37%）、叶片数（54.37%）和周径（56.43%）大幅降低。虽然没有发现植物死亡，但在 2% 的超细纤维培养物中，叶面积（62.44%）和植物总生物量（68.16%）的减少最为明显。因此，这些发现可能有助于更深入地理解多孔质微粒对土壤特性和地上植物生长的机制和影响。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Environmental Systems Research

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