使用 EDTA 和柠檬酸从污染土壤中柱浸提铬和镍。

Column leaching of chromium and nickel from a contaminated soil using EDTA and citric acid.

机构信息

Université de Limoges, Groupe de Recherche Eau Sol Environnement (GRESE), 123 Avenue Albert Thomas, 87060 Limoges, France.

出版信息

Environ Pollut. 2012 May;164:175-81. doi: 10.1016/j.envpol.2012.01.022. Epub 2012 Feb 22.

DOI:10.1016/j.envpol.2012.01.022

PMID:22361057

Abstract

This study investigates the column leaching of a soil contaminated mainly with Cr and Ni by using two chelants: citric acid (biodegradable) and EDTA (non-biodegradable) followed with water rinse. The chelants lead to Cr and Ni leaching, in addition to major elements (Ca, Fe, Mg, Al, Mn and Zn) showing the dissolution of soil mineral constituents. EDTA leaches more major elements and Ni than citric acid related to the respective stability of metal-chelant complexes; citric acid leaches more Cr than EDTA, certainly because of a substitution reaction with Cr(VI). In the case of alternating chelant/water applications, leaching occurs during the chelant applications, but also during water applications. In the case of chelant/water applications followed by continuous water application, both Cr and Ni leach over time. This increased mobility could be due to the residual chelant present in soil as well as to the dissolution/mobilization of mineral or organic soil fractions.

摘要

本研究采用两种螯合剂（可生物降解的柠檬酸和不可生物降解的 EDTA）对主要受 Cr 和 Ni 污染的土壤进行柱浸出实验，并用去离子水淋洗。结果表明，螯合剂不仅会导致 Cr 和 Ni 的浸出，还会导致 Ca、Fe、Mg、Al、Mn 和 Zn 等主要元素的溶解，从而破坏土壤矿物成分。EDTA 比柠檬酸浸出更多的主要元素和 Ni，这与金属-螯合剂配合物的稳定性有关；柠檬酸比 EDTA 浸出更多的 Cr，这肯定是因为与 Cr(VI)发生了取代反应。在交替使用螯合剂/水的情况下，浸出发生在螯合剂的应用过程中，但也发生在水的应用过程中。在螯合剂/水应用后再连续进行水应用的情况下，Cr 和 Ni 会随着时间的推移而浸出。这种增加的迁移性可能是由于土壤中残留的螯合剂以及矿物或有机土壤成分的溶解/迁移所致。

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使用 EDTA 和柠檬酸从污染土壤中柱浸提铬和镍。

Column leaching of chromium and nickel from a contaminated soil using EDTA and citric acid.

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