Application of Portable XRF Technology to Identification of Mineralization and Alteration along Drill in the Nihe Iron Deposit, Anhui, East China
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摘要: 便携式X射线荧光光谱(PXRF)是针对野外原位快速分析而发展起来的一项新技术,常被用于岩石露头地球化学研究和土壤重金属污染评价等方面.本研究以安徽省泥河铁矿钻孔为例,在野外对5个钻孔的岩心系统划分岩性段,利用便携式X射线荧光光谱仪原位测量每个岩性段的Fe、Mn、Cr、Co、Ni、Ti、V、Cu、Zn、Pb、Ag、Mo、K、Ca、As、Sb、Bi、Cs、Zr、Nb等元素含量,绘制钻孔各元素含量分布图.研究发现,(1)利用PXRF技术获得的岩心Fe元素高含量部位与根据化学分析得到的铁矿石品位数据而圈定的磁铁矿体范围吻合较好;(2)Fe元素和Fe-V-Mn-Cr-Ni-Ti-Bi组合异常、Zn元素和Zn-Cu-Cd组合异常分别对铁矿化和铜、锌矿化具有较好的指示作用;(3)K、Ca异常分别对钾长石化、硬石膏化等蚀变具有较好的指示作用.由此可见,PXRF技术在野外岩心矿化和蚀变信息识别中具有方便、快捷、实用、可靠、无损、成本低廉等优点.
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关键词:
- 便携式X射线荧光光谱 /
- 深部找矿 /
- 矿化 /
- 蚀变 /
- 泥河铁矿
Abstract: Portable X-ray fluorescence spectrum (PXRF) is a new analysis technique in-situ and is usually applied in both geochemical research at geological outcrop scale and heavy metal pollution assessment in soil. In this study, PXRF was used to recognize lithology section and to analyze the content of Fe, Mn, Cr, Co, Ni, Ti, V, Cu, Zn, Pb, Ag, Mo, K, Ca, As, Sb, Bi, Cs, Zr and Nb along 5 drill holes in the Nihe iron deposit, Anhui, East China. Based on these data, the spatial distribution of these elements is obtained. The results show that (1) the areas with high values of Fe obtained by PXRF have high spatial correlation with the area with high grade of Fe delineated by chemical analysis; (2) Fe anomalies, Fe-V-Mn-Cr-Ni-Ti-Bi anomalies, Zn anomalies and Zn-Cu-Cd anomalies are good indicators for Fe mineralization, Cu and Zn mineralization, respectively; and (3) K and Ca anomalies are good indictors for potash feldspar alteration and anhydrite alteration, respectively. These results indicate that PXRF is a convenient, quick, practical, reliable, and nondestructive technique of low cost for identifying of mineralization and alteration along drill in the field. -
图 1 泥河铁矿矿区地质简图(据安徽省区调队1981资料改编)
Fig. 1. Simplified geological map of the Nihe iron deposit
图 2 泥河铁矿Ⅰ纵剖面钻孔岩心Fe元素PXRF分析结果
Fig. 2. Fe composition in drills of No.Ⅰ section of the Nihe iron deposit obtained by PXRF
图 3 泥河铁矿ZK0501钻孔岩心部分元素含量分布
1.下白垩统双庙组;2.下白垩统砖桥组;3.闪长玢岩;4.粗安岩;5.辉石粗安岩;6.玄武粗安岩;7.闪长玢岩;8.火山碎屑岩;9.凝灰质粉砂岩;10.次生石英岩;11.黄铁矿脉;12.磁铁矿体
Fig. 3. Element compositions map of drill of No.ZK0501 of Nihe iron deposit
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