The distribution, influencing factors and ecological environment evaluation of soil germanium in Beibu Gulf of Guangxi Zhuang Autonomous Region
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摘要:
Ge在工业和医疗领域具有良好应用前景,有机锗化合物是一种毒性较低、具有较强抗癌活性的物质,富Ge土壤具有广阔的开发利用价值,但目前我国对土壤Ge的研究程度较低。基于广西壮族自治区多目标区域地球化学调查成果,对北部湾地区表层土壤及深层土壤Ge的空间分布特征进行了研究,阐明了不同成土母质地区表层土壤及深层土壤Ge含量情况,总结了影响土壤Ge含量的因素。结果表明,广西北部湾地区表层土壤Ge含量平均值是1.43 mg/kg,深层土壤Ge含量平均值是1.64 mg/kg。土壤Ge含量主要受控于成土母质,碳酸盐岩分布区土壤Ge含量最高,其次为花岗岩分布区、第四系沉积物分布区以及砂-页岩分布区。表层土壤与深层土壤Ge含量的比值显示表层土壤Ge含量受人为活动影响小。不同成土母质形成的土壤Ge含量的影响因素存在差异,花岗岩分布区表层土壤与深层土壤Ge含量主要受土壤黏土矿物、三水铝石以及石英的影响,碳酸盐岩、砂-页岩及第四系沉积物分布区表层土壤Ge含量主要受土壤黏土矿物、三水铝石、次生含铁矿物、无定形铁氧化物/氢氧化物、石英及有机质的影响,深层土壤Ge含量主要受土壤黏土矿物、三水铝石、次生含铁矿物、无定形铁氧化物/氢氧化物及石英的影响。研究区53.32%的表层土壤Ge含量达到较丰富水平,30.21%的表层土壤Ge含量达到丰富水平,对富Ge农作物的生长非常有利,具有开发利用价值。本文的研究成果旨在为土壤Ge的生态地球化学特征提供基础资料,为富Ge土地资源评价和富Ge农产品开发利用提供依据。
Abstract:Germanium has application prospects in both industrial and medical fields, organogermanium compounds exhibit low toxicity and antitumor activity. It is valuable to develop Ge-rich soil, whereas the research on soil Ge is still insufficient in China. Based on multi-purpose regional geochemical survey in Guangxi, the authors studied the spatial distribution of Ge in top soil and deep soil in Beibu Gulf in this paper. The Ge values of top soil as well as deep soil derived from various parent materials were elucidated, and the factors that influence soil Ge content were summarized. The results show that the average values of Ge in top soil and deep soil are 1.43 mg/kg and 1.64 mg/kg, respectively. The Ge values are critically controlled by parent materials, and the soil derived from carbonates has the highest Ge content, followed by soil that has originated from granites, Quaternary sediments, sandstones and shales. The ratios of top soil Ge values and deep soil Ge values indicate that Ge values of top soil are effected little by anthropogenic activities. The influencing factors of Ge contents vary in soils derived from different parent materials. As for top soil and deep soil derived from granites, Ge values are primarily influenced by clay minerals, gibbsite and quartz in soil. In contrast, for soils derived from carbonates, Quaternary sediments, sandstones and shales, top soil Ge values are primarily influenced by clay minerals, gibbsite, secondary Fe-bearing minerals, amorphous Fe oxyhydroxides, quartz and organic matters in soil, and deep soil Ge values are primarily influenced by clay minerals, gibbsite, secondary Fe-bearing minerals, amorphous Fe oxyhydroxides and quartz in soil. 53.32% of top soil have a slightly-rich level of Ge values and 30.21% of top soil have a rich level of Ge values, which are beneficial for Ge-rich agricultural crops cultivation and worthwhile for further exploitation. The objects of this study are to provide basic information for Ge ecogeochemistry, support Ge-rich soil and agricultural products development.
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Key words:
- germanium /
- soil /
- distribution characteristics /
- influencing factors /
- geological survey engineering /
- Beibu gulf /
- Guangxi
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表 2 研究区表层土壤和深层土壤Ge (mg/kg)地球化学参数
Table 2. Geochemical parameters of Ge (mg/kg) in top soil and deep soil in study area
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表 3 研究区不同成土母质形成的土壤Ge含量(mg/kg)特征
Table 3. Ge concentrations (mg/kg) of soil derived from various parent materials in study area
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表 4 土地质量评价锗等级划分标准
Table 4. Geochemical grade of soil Ge for land quality geochemical assessment
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表 5 研究区表层土壤Ge富集程度分类及面积
Table 5. Classification of top soil Ge enrichment level and regarding area in study area
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表 6 研究区表层土壤Ge含量与土壤主量元素及pH的相关性
Table 6. Correlation coefficients between Ge and major elements, pH in top soil in study area
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表 7 研究区深层土壤Ge含量与土壤主量元素及pH的相关性
Table 7. Correlation coefficients between Ge and major elements, pH in deep soil in study area
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