通过添加磷酸盐诱导地下水中的矿物沉淀

IF 0.9 4区 地球科学 Q4 GEOCHEMISTRY & GEOPHYSICS Geochemical Transactions Pub Date : 2011-10-26 DOI:10.1186/1467-4866-12-8
Karen E Wright, Thomas Hartmann, Yoshiko Fujita
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引用次数: 16

摘要

磷矿物诱导沉淀清除地下水中微量元素是一种潜在的污染含水层修复方法。工程降水方案的成功取决于产生的特定阶段、它们的形成速度和它们的长期稳定性。本研究的目的是研究在代表天然地下水的条件下磷酸钙矿物的沉淀。由于地下水中存在微生物,并且由于一些提出的磷矿沉淀方案依赖于原生微生物种群的刺激,我们还测试了在沉淀介质中添加细菌细胞(初始密度为105和107 mL-1)的效果。此外,我们还测试了丙酸、异戊酸、甲酸和丁酸的微量混合物(总浓度为0.035 mM)的效果。在所有研究条件下,矿物沉淀的总体过程相似,最初形成无定形磷酸钙,并在一周内转变为低结晶羟基磷灰石(HAP)。细菌细胞的存在似乎延迟了沉淀,尽管在实验结束时,所有处理的总体沉淀程度是相似的。最终析出物的化学计量学以及利用x射线衍射数据进行的Rietveld结构细化表明,有机酸和细菌细胞的存在导致晶格参数a增大和c减小,细胞浓度越高导致畸变越大。与对照相比,细胞和有机酸处理降低了固体对锶的吸收。我们的研究结果表明,最初在工程沉淀应用中形成的矿物质可能不是控制污染物长期固定的矿物质。此外,与无细胞体系相比,细菌细胞的存在似乎与HAP沉淀延迟、晶格参数变化以及微量元素掺入减少有关。以增强磷矿沉淀为基础的被微量金属污染的地下水修复方案可能需要考虑到这些现象,特别是如果修复方法依赖于增加原位微生物种群。
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Inducing mineral precipitation in groundwater by addition of phosphate

Induced precipitation of phosphate minerals to scavenge trace elements from groundwater is a potential remediation approach for contaminated aquifers. The success of engineered precipitation schemes depends on the particular phases generated, their rates of formation, and their long term stability. The purpose of this study was to examine the precipitation of calcium phosphate minerals under conditions representative of a natural groundwater. Because microorganisms are present in groundwater, and because some proposed schemes for phosphate mineral precipitation rely on stimulation of native microbial populations, we also tested the effect of bacterial cells (initial densities of 105 and 107 mL-1) added to the precipitation medium. In addition, we tested the effect of a trace mixture of propionic, isovaleric, formic and butyric acids (total concentration 0.035 mM).

The general progression of mineral precipitation was similar under all of the study conditions, with initial formation of amorphous calcium phosphate, and transformation to poorly crystalline hydroxylapatite (HAP) within one week. The presence of the bacterial cells appeared to delay precipitation, although by the end of the experiments the overall extent of precipitation was similar for all treatments. The stoichiometry of the final precipitates as well as Rietveld structure refinement using x-ray diffraction data indicated that the presence of organic acids and bacterial cells resulted in an increasing a and decreasing c lattice parameter, with the higher concentration of cells resulting in the greatest distortion. Uptake of Sr into the solids was decreased in the treatments with cells and organic acids, compared to the control.

Our results suggest that the minerals formed initially during an engineered precipitation application for trace element sequestration may not be the ones that control long-term immobilization of the contaminants. In addition, the presence of bacterial cells appears to be associated with delayed HAP precipitation, changes in the lattice parameters, and reduced incorporation of trace elements as compared to cell-free systems. Schemes to remediate groundwater contaminated with trace metals that are based on enhanced phosphate mineral precipitation may need to account for these phenomena, particularly if the remediation approach relies on enhancement of in situ microbial populations.

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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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