Formulation and Evaluation of Slow-Release Fertilizer from Agricultural and Industrial Wastes for Remediation of Crude Oil-Polluted Soils

Day 2 Tue, August 06, 2019 Pub Date : 2019-08-05 DOI:10.2118/198815-MS

C. Obieze, C. Chikere, R. Adeleke, O. Akaranta

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引用次数: 6

Abstract

Fertilizers are used to enhance the degradation and sequestration of oil-polluted environments, but a decrease in fertilizer efficiency can lead to severe environmental consequences. The aim of this study was, therefore, to formulate a slow release fertilizer using nutrient-rich, ecofriendly and readily available agricultural and industrial wastes. The formulated fertilizer was coated with a renewable, nontoxic and biodegradable material which was then tested against commercial NPK fertilizer for its effect on hydrocarbon degradation rate. Crude oil polluted soil from an artisanal refining site was used to evaluate the efficiency of the fertilizers. Next-generation sequencing technique was used to determine the microbiome of the oil-polluted soil. Metabolic fingerprints were also determined as remediation progressed. Other parameters monitored were pH, extractable total petroleum hydrocarbons (ETPH), NO3- -N, total phosphate and total potassium. Initial ETPH of the polluted soil was 16,388 mg/kg which reduced to 2,250.21 mg/kg after 56 days of remediation. The formulated fertilizer gradually led to an increase in soil pH from being slightly acidic (5.6) to near neutral (6.9), while the commercial NPK fertilizer led to a further decrease in soil pH. Both fertilizers enhanced degradation without significant differences, however, the formulated fertilizer greatly improved microbial diversity. Proteobacteria, Chloroflexi and Acidobacteria dominated the soil microbiome with Acidocella being the leading bacterial genus. Signature metabolites identified included benzenamine, cyclobutanone, octadecane and hexadecane which were all related to hydrocarbon biodegradation. The study revealed that the formulated fertilizer effectively enhanced the restoration of oil-polluted soils as well as microbial diversity and soil fertility. It also shows that acid-loving bacteria are important in the bioremediation of acidic oil-polluted soils.

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用于原油污染土壤修复的工农业废弃物缓释肥料配方及评价

肥料的使用是为了加强石油污染环境的降解和隔离，但肥料效率的降低会导致严重的环境后果。因此，本研究的目的是利用营养丰富、生态友好且易于获得的农业和工业废物配制一种缓释肥料。用可再生的、无毒的、可生物降解的材料包覆该配方肥料，并与商业氮磷钾肥料对比，测试其对碳氢化合物降解率的影响。以某手工炼制场地原油污染土壤为研究对象，评价了化肥的施用效果。采用新一代测序技术对石油污染土壤微生物组进行了测定。随着修复的进行，也测定了代谢指纹。监测的其他参数包括pH、可提取总石油烃(ETPH)、NO3- - n、总磷酸盐和总钾。污染土壤的初始ETPH为16388 mg/kg，经过56 d的修复，ETPH降至2250.21 mg/kg。配方肥使土壤pH由微酸性(5.6)逐渐升高到接近中性(6.9)，而商品NPK肥使土壤pH进一步降低。两种肥料对土壤的降解作用均无显著差异，但配方肥极大地改善了微生物多样性。变形杆菌、绿杆菌和酸杆菌在土壤微生物群中占主导地位，其中酸杆菌属占主导地位。鉴定出的特征代谢物包括苯胺、环丁酮、十八烷和十六烷，这些代谢物都与烃类生物降解有关。研究表明，该配方肥料能有效促进油质污染土壤的修复，提高土壤微生物多样性和肥力。这也表明嗜酸菌在酸性油污染土壤的生物修复中具有重要作用。

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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Day 2 Tue, August 06, 2019

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