碱性条件下Ni（II）、Co（II）和Fe（II）的三络合选择性及其对碳酸盐沉淀的影响

IF 3.4 3区地球科学 Q1 GEOCHEMISTRY & GEOPHYSICS

Applied Geochemistry Pub Date : 2025-07-28 DOI:10.1016/j.apgeochem.2025.106512

J.L. Houghton , J.M. Haywood , Y. Wang , Y.S. Jun , D.A. Fike

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引用次数: 0

摘要

低品位超镁铁质矿床的临界元素同步回收和离地碳矿化引起了越来越多的关注。在碳酸盐成矿过程中，需要了解金属络合有机配体对超镁质岩石中各种二价金属的选择性，以优化这一过程。在这里，我们评估了2-氨基-2-（羟甲基）-1,3-丙二醇（即Tris）作为双齿配体的模型，该配体在25°C和80°C的碳酸缓冲溶液中，在碱性条件下（pH 8-10.5）将二价金属与胺和醇结合。质子化的Tris与金属离子形成较强的配合物，对Ni(II) >等微量金属具有选择性；有限公司(II)在Fe（II）在碳酸盐沉淀过程中，随着温度和pH的降低，速率降低，但选择性增加。在25℃时，无论Tris的存在量或pH值如何，都形成亚稳态无定形水合碳酸盐。在80°C和pH 8条件下，形成的Co和Fe碳酸盐是赤铁矿群矿物(Co2CO3（OH)2（H2O）和Fe2CO3(OH)2）和纯碳酸盐（球钴矿：CoCO3和铁铁矿：FeCO3）的混合物，后者随着Tris浓度的增加而更加稳定。在25°C不含Tris的混合金属溶液中，当Fe:Ni或Fe:Co为2:1时，Fe增加了Ni或Co碳酸盐的析出速率。然而，随着Tris浓度的增加，Ni或Co的存在抑制了Fe碳酸盐岩的析出。在80℃无Tris时，Ni或Co取代铁楚卡云石（Fe2CO3(OH)2）晶格，提高了Ni或Co碳酸盐的析出率。增加Tris浓度只会轻微抑制Fe和Co的析出，但会使Ni的析出速度减慢10倍，Fe逐渐分解成更纯的碳酸盐相，具有不同的结晶形态。这些结果表明，在较低温度和微碱性条件下，含铁超镁铁质矿床的碳矿化过程中，双齿含胺配体可能有效地回收镍和钴。

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Selectivity of tris complexation for Ni(II), Co(II), and Fe(II) and its effect on carbonate precipitation under alkaline conditions

Simultaneous critical element recovery and ex-situ carbon mineralization of low-grade ultramafic deposits have garnered increasing interest. Understanding the selectivity of metal complexing organic ligands for various divalent metals present in ultramafic rocks during carbonate mineralization is required to optimize this process. Here we evaluate 2-amino-2-(hydroxymethyl)-1,3-propanediol (i.e., Tris) as a model for bidentate ligands that bind divalent metals with both amine and alcohol groups in alkaline conditions (pH 8–10.5) at 25 °C and 80 °C in carbonate-buffered solutions. Protonated Tris forms a stronger complex with metal ions and is selective for trace metals with Ni(II) > Co(II) > Fe(II) during carbonate precipitation, with the rates decreasing but selectivity increasing at lower temperature and lower pH. At 25 °C, metastable amorphous hydrated carbonates form, regardless of the amount of Tris present or pH values. At 80 °C and pH 8, the Co and Fe carbonates that form are a mixture of rosasite-group minerals (Co₂CO₃(OH)₂(H₂O) and Fe₂CO₃(OH)₂) and pure carbonates (sphaerocobaltite: CoCO₃ and siderite: FeCO₃), with the latter more stabilized with increasing Tris concentration. In mixed metal solutions without Tris at 25 °C where Fe:Ni or Fe:Co is 2:1, Fe increases the rates of Ni or Co carbonate precipitation. However, with increasing Tris concentration the presence of Ni or Co inhibits Fe carbonate precipitation. At 80 °C without Tris, Ni or Co substitute into the iron chukanovite (Fe₂CO₃(OH)₂) lattice, increasing Ni or Co carbonate precipitation rates. Increasing Tris concentration only slightly inhibits Fe and Co precipitation, but slows Ni precipitation up to 10 times, with Fe progressively partitioning into more pure carbonate phases with distinct crystalline morphologies. These findings suggest bidentate amine-bearing ligands may be effective at Ni and Co recovery during carbon mineralization of Fe-bearing ultramafic deposits at relatively low temperatures and slightly alkaline pH.

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来源期刊

Applied Geochemistry 地学-地球化学与地球物理

CiteScore

6.10

自引率

8.80%

发文量

272

审稿时长

65 days

期刊介绍： Applied Geochemistry is an international journal devoted to publication of original research papers, rapid research communications and selected review papers in geochemistry and urban geochemistry which have some practical application to an aspect of human endeavour, such as the preservation of the environment, health, waste disposal and the search for resources. Papers on applications of inorganic, organic and isotope geochemistry and geochemical processes are therefore welcome provided they meet the main criterion. Spatial and temporal monitoring case studies are only of interest to our international readership if they present new ideas of broad application. Topics covered include: (1) Environmental geochemistry (including natural and anthropogenic aspects, and protection and remediation strategies); (2) Hydrogeochemistry (surface and groundwater); (3) Medical (urban) geochemistry; (4) The search for energy resources (in particular unconventional oil and gas or emerging metal resources); (5) Energy exploitation (in particular geothermal energy and CCS); (6) Upgrading of energy and mineral resources where there is a direct geochemical application; and (7) Waste disposal, including nuclear waste disposal.