MgCl2和磷酸盐改性城市污泥生物炭中潜在有毒元素的稳定性

Qiqi Huang, Siqi Chen, Jinhao Lin, Jingzi Beiyuan, Jin Wang, Juan Liu, Yundang Wu, Xiaolian Wu, Fuhua Li, Wenbing Yuan, Chengrong Nie
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引用次数: 4

摘要

与填埋和焚烧等其他典型技术相比,城市污水污泥可以热解为生物炭,更好地利用营养物质和稳定碳。然而,污泥衍生的生物炭可能含有大量的潜在有毒元素(pte),如Zn、Cu、Cr、Ni、Pb和as。较高的热解温度可以提高pte在生物炭中的稳定性,通过不同的改性可以进一步提高pte在生物炭中的稳定性。为了提高pte的稳定性,分别在300℃下对po4进行改性,在700℃下对cl进行改性。为了评估pte在生物炭中的稳定性,进行了各种浸出试验,包括合成沉淀浸出法(SPLP)、毒性特征浸出法(TCLP)、五乙酸二乙烯三胺(DTPA)提取法和体外简单生物可及性提取法(SBET)。利用扫描电镜-能谱仪(SEM-EDS)和x射线衍射仪(XRD)研究了原始生物炭和改性生物炭的形态结构、元素定位和矿物形成。我们的研究结果表明,热解降低了大多数pte的浸出性、流动性、植物利用度和生物可及性,但pte的总含量升高,特别是在700°C时。一般来说,磷酸盐和MgCl2的修饰增强了pte在生物炭中的稳定性。然而,应该注意的是,p修饰的生物炭中pte的生物可及性高于cl修饰的生物炭,这与酸性条件下磷酸盐沉淀的溶解有关(pH<2)。此外,与在700°C下生产的未经改性的生物炭相比,cl改性导致更高的植物有效锌和Cu以及生物可达锌。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Stability of potentially toxic elements in municipal sludge biochars modified by MgCl2 and phosphate

Stability of potentially toxic elements in municipal sludge biochars modified by MgCl2 and phosphate

Municipal wastewater sludge can be pyrolyzed as biochars to better use nutrients and stabilize carbon compared with other typical technologies, such as landfill and incineration. However, sludge-derived biochars might contain large amounts of potentially toxic elements (PTEs), such as Zn, Cu, Cr, Ni, Pb, and As. The stability of PTEs in biochars might be improved by higher pyrolytic temperatures, which can be further improved by different modifications. Herein, PO4-modification at 300 °C and Cl-modification at 700 °C were carried out, respectively, to enhance the stability of PTEs. Various leaching tests have been performed to assess the stability of PTEs in biochars, including the synthetic precipitation leaching procedure (SPLP), toxicity characteristic leaching procedure (TCLP), diethylenetriamine pentaacetate (DTPA) extraction, and in vitro simple bioaccessibility extraction test (SBET). The morphological structure, elemental mapping, and mineral formation of the pristine and modified biochars were studied by scanning electron microscopy–energy-dispersive X-ray spectroscopy (SEM–EDS) and X-ray diffraction (XRD). Our results suggested that the leachability, mobility, plant-availability, and bioaccessibility of most PTEs were decreased by pyrolysis, yet the total contents of PTEs were elevated, especially at 700 °C. Generally, modification by phosphates and MgCl2 enhanced the stability of PTEs in biochars. Nevertheless, it should be noted that higher bioaccessibility of PTEs was observed in biochars of P-modification than Cl-modification, which is associated with the dissolution of phosphate precipitates under acidic conditions (pH<2). Additionally, Cl-modification leads to higher plant-available Zn and Cu and bioaccessible Zn compared with the unmodified biochar produced at 700 °C.

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