Accelerated mineral bio-carbonation of coarse residue kimberlite material by inoculation with photosynthetic microbial mats

IF 0.9 4区 地球科学 Q4 GEOCHEMISTRY & GEOPHYSICS
Thomas Ray Jones, Jordan Poitras, Emma Gagen, David John Paterson, Gordon Southam
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引用次数: 1

Abstract

Microbiological weathering of coarse residue deposit (CRD) kimberlite produced by the Venetia Diamond Mine, Limpopo, South Africa enhanced mineral carbonation relative to untreated material. Cultures of photosynthetically enriched biofilm produced maximal carbonation conditions when mixed with kimberlite and incubated under near surface conditions. Interestingly, mineral carbonation also occurred in the dark, under water-saturated conditions. The examination of mineralized biofilms in ca. 150 µm-thick-sections using light microscopy, X-ray fluorescence microscopy (XFM) and backscatter electron—scanning electron microscopy-energy dispersive x-ray spectrometry demonstrated that microbiological weathering aided in producing secondary calcium/magnesium carbonates on silicate grain boundaries. Calcium/magnesium sulphate(s) precipitated under vadose conditions demonstrating that evaporites formed upon drying. In this system, mineral carbonation was only observed in regions possessing bacteria, preserved within carbonate as cemented microcolonies. 16S rDNA molecular diversity of bacteria in kimberlite and in natural biofilms growing on kimberlite were dominated by Proteobacteria that are active in nitrogen, phosphorus and sulphur cycling. Cyanobacteria based enrichment cultures provided with nitrogen & phosphorus (nutrients) to enhance growth, possessed increased diversity of bacteria, with Proteobacteria re-establishing themselves as the dominant bacterial lineage when incubated under dark, vadose conditions consistent with natural kimberlite. Overall, 16S rDNA analyses revealed that weathered kimberlite hosts a diverse microbiome consistent with soils, metal cycling and hydrocarbon degradation. Enhanced weathering and carbonate-cemented microcolonies demonstrate that microorganisms are key to mineral carbonation of kimberlite.

通过接种光合微生物垫加速金伯利岩粗渣材料的矿物生物碳化作用
南非林波波省Venetia钻石矿生产的金伯利岩粗渣矿床(CRD)的微生物风化作用相对于未经处理的材料增强了矿物碳酸化。当与金伯利岩混合并在近地表条件下培养时,光合作用富集的生物膜产生最大的碳酸化条件。有趣的是,矿物碳酸化也发生在黑暗中,在水饱和的条件下。利用光学显微镜、x射线荧光显微镜(XFM)和后向散射电子扫描电子显微镜-能量色散x射线光谱法对约150 μ m厚的矿化生物膜进行了检查,结果表明微生物风化有助于在硅酸盐晶界上产生次生碳酸钙/碳酸镁。硫酸钙/硫酸镁在真空条件下沉淀,表明蒸发岩是在干燥后形成的。在这个系统中,矿物碳酸化只在有细菌的区域被观察到,这些细菌以胶结的微菌落形式保存在碳酸盐中。金伯利岩和生长在金伯利岩上的天然生物膜细菌的16S rDNA分子多样性以参与氮、磷、硫循环的变形菌群为主。提供氮的蓝藻富营养化培养;磷(营养物)促进生长,增加了细菌的多样性,当在与自然金伯利岩相一致的黑暗、真空条件下孵育时,变形杆菌重新确立了自己作为主要细菌谱系的地位。总的来说,16S rDNA分析显示,风化的金伯利岩拥有与土壤、金属循环和碳氢化合物降解一致的多种微生物群。增强的风化作用和碳酸盐胶结的微菌落表明微生物是金伯利岩矿物碳酸化的关键。
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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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