Cryptomelane formation from nanocrystalline vernadite precursor: a high energy X-ray scattering and transmission electron microscopy perspective on reaction mechanisms

IF 0.9 4区 地球科学 Q4 GEOCHEMISTRY & GEOPHYSICS Geochemical Transactions Pub Date : 2015-09-02 DOI:10.1186/s12932-015-0028-y
Sylvain Grangeon, Alejandro Fernandez-Martinez, Fabienne Warmont, Alexandre Gloter, Nicolas Marty, Agnieszka Poulain, Bruno Lanson
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引用次数: 33

Abstract

Vernadite is a nanocrystalline and turbostratic phyllomanganate which is ubiquitous in the environment. Its layers are built of (MnO6)8? octahedra connected through their edges and frequently contain vacancies and? (or) isomorphic substitutions. Both create a layer charge deficit that can exceed 1 valence unit per layer octahedron and thus induces a strong chemical reactivity. In addition, vernadite has a high affinity for many trace elements (e.g., Co, Ni, and Zn) and possesses a redox potential that allows for the oxidation of redox-sensitive elements (e.g., As, Cr, Tl). As a result, vernadite acts as a sink for many trace metal elements. In the environment, vernadite is often found associated with tectomanganates (e.g., todorokite and cryptomelane) of which it is thought to be the precursor. The transformation mechanism is not yet fully understood however and the fate of metals initially contained in vernadite structure during this transformation is still debated. In the present work, the transformation of synthetic vernadite (δ-MnO2) to synthetic cryptomelane under conditions analogous to those prevailing in soils (dry state, room temperature and ambient pressure, in the dark) and over a time scale of ~10?years was monitored using high-energy X-ray scattering (with both Bragg-rod and pair distribution function formalisms) and transmission electron microscopy.

Migration of Mn3+ from layer to interlayer to release strains and their subsequent sorption above newly formed vacancy in a triple-corner sharing configuration initiate the reaction. Reaction proceeds with preferential growth to form needle-like crystals that subsequently aggregate. Finally, the resulting lath-shaped crystals stack, with n?×?120° (n?=?1 or 2) rotations between crystals. Resulting cryptomelane crystal sizes are ~50–150?nm in the ab plane and ~10–50?nm along c*, that is a tenfold increase compared to fresh samples.

The presently observed transformation mechanism is analogous to that observed in other studies that used higher temperatures and (or) pressure, and resulting tectomanganate crystals have a number of morphological characteristics similar to natural ones. This pleads for the relevance of the proposed mechanism to environmental conditions.

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纳米晶vernadite前驱体生成隐黑烷:反应机理的高能x射线散射和透射电镜观察
Vernadite是一种在环境中普遍存在的纳米晶体、涡层状叶芒酸盐。它的层是由(MnO6)8?通过边缘连接的八面体通常包含空位和?(或)同构取代。两者都产生层电荷亏缺,每层八面体可超过1价单位,从而引起强烈的化学反应性。此外,vernadite对许多微量元素(如Co, Ni和Zn)具有高亲和力,并具有氧化还原电位,允许氧化还原敏感元素(如As, Cr, Tl)的氧化。因此,绿铅矿作为许多微量金属元素的汇。在环境中,vernadite经常与辉钼矿(例如,辉钼矿和隐钼矿)伴生,被认为是辉钼矿的前体。然而,转变机制尚未完全了解,并且在转变过程中最初包含在vernadite结构中的金属的命运仍然存在争议。在本研究中,在类似于土壤中普遍存在的条件下(干燥状态、室温和环境压力、黑暗),在~10?使用高能x射线散射(同时使用布拉格棒和对分布函数形式)和透射电子显微镜对其进行监测。Mn3+从层间迁移到层间释放应变,并在三角共享构型中吸附在新形成的空位上方,引发了反应。反应以优先生长的方式进行,形成随后聚集的针状晶体。最后,得到的板条状晶体以n?×?120°(n = ?晶体之间的1或2)旋转。所得隐晶石晶体尺寸为~50 ~ 150?ab平面的Nm和~ 10-50 ?Nm沿着c*,与新鲜样品相比,这是十倍的增长。目前观察到的转化机制与其他使用更高温度和(或)压力的研究中观察到的类似,并且产生的tectomanganate晶体具有许多与天然晶体相似的形态特征。这就证明了所提议的机制与环境条件的相关性。
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来源期刊
Geochemical Transactions
Geochemical Transactions 地学-地球化学与地球物理
CiteScore
3.70
自引率
4.30%
发文量
2
审稿时长
>12 weeks
期刊介绍: Geochemical Transactions publishes high-quality research in all areas of chemistry as it relates to materials and processes occurring in terrestrial and extraterrestrial systems.
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