Rare earth elements binding humic acids: NICA-Donnan modelling

IF 2 4区环境科学与生态学 Q3 CHEMISTRY, ANALYTICAL Environmental Chemistry Pub Date : 2023-01-01 DOI:10.1071/en23049

Alba Otero-Fariña, Noémie Janot, Rémi Marsac, Charlotte Catrouillet, Jan E. Groenenberg

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Abstract

Environmental context Rare earth elements (REEs) are technologically critical elements released into the environment by various anthropogenic activities, and whose ecotoxicological impacts are still largely unknown. REE binding to natural organic matter (NOM) is key to understand their fate and bioavailability in the environment. With this work, it is now possible to predict REE binding to NOM in various environments using various speciation software (ECOSAT, ORCHESTRA, Visual MINTEQ).Rationale Understanding rare earth element (REE) speciation in different natural environments is important to evaluate their environmental risks because different chemical species of an element may have different bioavailability and toxicity. REEs have a great affinity for particulate and dissolved organic matter, particularly fulvic and humic acids (HAs). Thus, the use of humic ion binding models may help to understand and predict the behaviour and speciation of these species in surface waters, groundwaters and soils.Methodology In this work, we used previously published experimental datasets to parameterise the NICA-Donnan model for REEs binding with HAs, using the model optimisation tool PEST-ORCHESTRA. We propose using linear free energy relationships (LFERs) to constrain the number of parameters to optimise.Results We determined a coherent NICA-Donnan parameter set for the whole REEs series being compatible with available generic NICA-Donnan parameters for other metals. The impact of pH, ionic strength and REE/HA ratio as well as the presence of competitors (Fe3+, Al3+ and Cu2+) on model results is analysed.Discussion We consolidate confidence in our derived NICA-Donnan parameters for REEs by comparing them with the Irving–Rossotti LFER. We also show the general applicability of this relationship to predict and constrain metal-binding parameters for the NICA-Donnan model. We discuss observed shortcomings and provide suggestions for potential improvement of NICA-Donnan modelling.

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稀土元素结合腐植酸:NICA-Donnan模型

稀土元素(ree)是各种人为活动释放到环境中的技术关键元素，其生态毒理学影响在很大程度上仍然未知。稀土元素与天然有机质(NOM)的结合是了解它们在环境中的命运和生物利用度的关键。通过这项工作，现在可以使用各种物种形成软件(ECOSAT, ORCHESTRA, Visual MINTEQ)预测REE在各种环境中与NOM的结合。了解稀土元素(REE)在不同自然环境中的形态对评估其环境风险很重要，因为一种元素的不同化学形态可能具有不同的生物利用度和毒性。稀土元素对颗粒和溶解的有机物有很大的亲和力，特别是黄腐酸和腐植酸(HAs)。因此，使用腐殖质离子结合模型可能有助于了解和预测这些物种在地表水、地下水和土壤中的行为和物种形成。在这项工作中，我们使用先前发表的实验数据集，使用模型优化工具PEST-ORCHESTRA，对REEs与HAs结合的NICA-Donnan模型进行参数化。我们建议使用线性自由能关系(LFERs)来约束要优化的参数数量。结果我们确定了整个稀土系列的一致性NICA-Donnan参数集，该参数集与其他金属的可用通用NICA-Donnan参数集兼容。分析了pH、离子强度、REE/HA比以及竞争对手(Fe3+、Al3+和Cu2+)的存在对模型结果的影响。通过与Irving-Rossotti LFER进行比较，我们巩固了对所得稀土元素NICA-Donnan参数的信心。我们还展示了这种关系在预测和约束NICA-Donnan模型的金属结合参数方面的一般适用性。我们讨论了观察到的缺点，并提出了NICA-Donnan模型的潜在改进建议。

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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来源期刊

Environmental Chemistry 环境科学-分析化学

CiteScore

4.50

自引率

0.00%

发文量

审稿时长

2.7 months

期刊介绍： Environmental Chemistry publishes manuscripts addressing the chemistry of the environment (air, water, earth, and biota), including the behaviour and impacts of contaminants and other anthropogenic disturbances. The scope encompasses atmospheric chemistry, geochemistry and biogeochemistry, climate change, marine and freshwater chemistry, polar chemistry, fire chemistry, soil and sediment chemistry, and chemical aspects of ecotoxicology. Papers that take an interdisciplinary approach, while advancing our understanding of the linkages between chemistry and physical or biological processes, are particularly encouraged. While focusing on the publication of important original research and timely reviews, the journal also publishes essays and opinion pieces on issues of importance to environmental scientists, such as policy and funding. Papers should be written in a style that is accessible to those outside the field, as the readership will include - in addition to chemists - biologists, toxicologists, soil scientists, and workers from government and industrial institutions. All manuscripts are rigorously peer-reviewed and professionally copy-edited. Environmental Chemistry is published with the endorsement of the Commonwealth Scientific and Industrial Research Organisation (CSIRO) and the Australian Academy of Science.