食物垃圾及其生物炭对土壤特性和微塑料污染土壤中生菜生长的不同影响

IF 2.3 3区 农林科学 Q3 FOOD SCIENCE & TECHNOLOGY
Kumuduni Niroshika Palansooriya, Piumi Amasha Withana, Yoonah Jeong, Mee Kyung Sang, Yoora Cho, Geonwook Hwang, Scott X. Chang, Yong Sik Ok
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引用次数: 0

摘要

在土壤中添加有机添加剂,如食物垃圾(FW)和生物炭,是一种众所周知的提高土壤肥力和改善土壤整体健康的农艺方法。然而,在受微塑料(MP)污染的土壤-植物系统中,人们对厨余垃圾和生物碳对土壤性质的单独影响和综合影响仍然知之甚少。为了填补这一知识空白,我们进行了一项田间试验,研究聚苯乙烯微塑料、粉尘和由粉尘衍生的生物炭对土壤性质和莴苣生长的单独和综合影响。添加 MPs 不会影响土壤化学性质。然而,施用 FW 和生物炭会提高土壤 pH 值,在生物炭和 MPs 的组合处理中,pH 值最高(8.2)。尽管存在 MPs,施用 FW 仍显著提高了土壤导电率(EC;2.04 dS m-1)、可利用氮(NO3--N:325.5 mg kg-1,NH4+-N:105.2 mg kg-1)、可利用磷(88.4 mg kg-1)和总可交换阳离子(18.6 cmol(+) kg-1)。不过,种植莴苣后,这些数值都有所下降。在种植莴苣的土壤中,MPs 和生物炭的共存降低了土壤中 46.2% 的荧光素二乙酸水解酶活性和 94.0% 的脲酶活性。添加 FW 可使酸性磷酸酶活性提高一倍,而 FW 及其与 MPs 共存则降低了α多样性。放线菌的相对丰度随 MP 的施用而降低,而酸性杆菌和放线菌的相对丰度则随 FW 的处理而降低。在施用 FW 和生物炭的土壤中,革囊菌和硝化菌的相对丰度有所下降。在添加了 FW 的土壤中,固着菌和变形菌的相对丰度最高,而在添加了生物炭的土壤中,放线菌的相对丰度最高。施用 FW 对莴苣的生长有负面影响。总之,MPs 与 FW 或生物炭共存对土壤性质和莴苣生长的影响有限,FW 和生物炭是改变土壤-植物系统的主要因素。未来的研究应探讨不同的 MPs 及其与有机土壤改良剂在不同管理实践下对土壤性质和作物生长的影响。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Contrasting effects of food waste and its biochar on soil properties and lettuce growth in a microplastic-contaminated soil

The incorporation of organic amendments, such as food waste (FW) and biochar, into soil is an established agronomic practice known for enhancing soil fertility and improving overall soil health. However, the individual and combined effects of FW and biochar on soil properties in microplastic (MP)-contaminated soil–plant systems remain poorly understood. To address this knowledge gap, we conducted a field experiment to investigate the individual and combined effects of polystyrene MPs, FW, and FW-derived biochar on soil properties and lettuce growth. Soil chemical properties were unaffected by the addition of MPs. However, the application of FW and biochar increased the soil pH, with the highest pH (8.2) observed in the combined treatment of biochar and MPs. Despite the presence of MPs, FW application resulted in notable increases in soil electrical conductivity (EC; 2.04 dS m−1), available nitrogen (NO3–N: 325.5 mg kg−1, NH4+–N: 105.2 mg kg−1), available phosphorus (88.4 mg kg−1), and total exchangeable cations (18.6 cmol(+) kg−1). However, these values decreased after lettuce cultivation. In soil cultivated with lettuce, the coexistence of MPs and biochar reduced soil Fluorescein diacetate hydrolase enzyme activity by 46.2% and urease activity by 94.0%. FW addition doubled acid phosphatase activity, whereas FW and its coexistence with MPs decreased alpha diversity. The relative abundance of Actinobacteria decreased with MP application, whereas that of Acidobacteria and Actinobacteria decreased with FW treatment. Gemmatimonadetes and Nitrospirae decreased in soil treated with FW and biochar. The highest relative abundances of Firmicutes and Proteobacteria were observed in the FW-added soils, and Planctomycetes were the highest in the biochar-added soils. FW application negatively affected lettuce growth. Overall, the coexistence of MPs with FW or biochar had limited effects on soil properties and lettuce growth, with FW and biochar serving as the primary factors in modifying soil–plant systems. Future studies should investigate the effects of different MPs and their interactions with organic soil amendments on soil properties and crop growth under different management practices.

Graphical Abstract

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来源期刊
Applied Biological Chemistry
Applied Biological Chemistry Chemistry-Organic Chemistry
CiteScore
5.40
自引率
6.20%
发文量
70
审稿时长
20 weeks
期刊介绍: Applied Biological Chemistry aims to promote the interchange and dissemination of scientific data among researchers in the field of agricultural and biological chemistry. The journal covers biochemistry and molecular biology, medical and biomaterial science, food science, and environmental science as applied to multidisciplinary agriculture.
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