| 光谱学与光谱分析 |
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| The NIR Spectral Characteristics and Meaning of Fault Gouge from Kaxiutata Iron Deposit, Inner Mongolia |
| DAI Dong-le, CAO Jian-jin* |
| School of Earth Science, Sun Yat-sen University, Key Lab of Geological Process and Mineral Resources Expedition of Guangdong Province, Guangzhou 510275, China |
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Abstract Kaxiutata iron deposit is a skarn type magnetite deposit located in Inner Mongolia, China. There are many faults developed after metallogenic period. In this study, NIR analysis method is adopted to identify the mineral composition of subsurface and surface fault gouge from mining area. Through the characteristic peaks, it is was identified that there are mainly mafic mineral in the subsurface fault gouge and salic minerals in the surface fault gouge, the sand sample for comparison contain both two types of minerals. The result of analysis of all three sets of sample is in accordance with the geological background of the sampling spot. According to this research, due to the main composition of the fault gouge in the mineralization area are clay formed due to the faulting movement and altered minerals formed in early metallogenic period. NIR analysis technology is suitable for this type of sample, to use this technology, we can identify the clay mineral in the fault gouge, and further speculate the composition of protolith of clay,we can also indentify the altered minerals formed in metallogenic period, and provide useful information for study of hydrothermal deposit.
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Received: 2015-09-05
Accepted: 2015-12-22
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Corresponding Authors:
CAO Jian-jin
E-mail: eescjj@mail.sysu.edu.cn
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[1] Buatier M, Chauvet A, Kanitpanyacharoen W, et al. Journal of Structural Geology, 2012, 34: 77.
[2] LIN Chuan-yong, SHI Lan-bin, LIU Xing-song, et al(林传勇,史兰斌,刘行松,等). Earthquake Research in China(中国地震), 1995, 11(1): 26.
[3] XIU lian-cun, ZHENG Zhi-zhong, YU Zheng-kui, et al(修连存, 郑志忠, 俞正奎, 等). Rock and Mineral Analysis(岩矿测试), 2009, 28(6): 519.
[4] ZHANG Jian-guo, YANG Zi-an, SHI Fei-fei, et al(张建国, 杨自安, 石菲菲, 等). Mineral Resources and Geology(矿产与地质), 2011, 25(3): 236.
[5] Hunt G R, Salisbury J W, Lenhoff C J. Modern Geology,1973, 4(2): 95.
[6] McCord T B, Hansen G B, Matson D L, et al. Journal of Geophysical Research-Planets, 1999, 104(E5): 11827.
[7] LI Ying-kui, CAO Jian-jin, WU Zheng-quan, et al(李映葵, 曹建劲, 吴政权, 等). Spectroscopy and Spectral Analysis(光谱学与光谱分析), 2015, 35(1): 83.
[8] YI Ze-bang, CAO Jian-jin, LUO Song-ying, et al (易泽邦, 曹建劲, 罗松英, 等). Spectroscopy and Spectral Analysis (光谱学与光谱分析), 2014, 34(8): 2076.
[9] Jerry Workerman, Jr Lois Weyer(杰尔·沃克曼,洛伊斯·文依). Traslated by CHU Xiao-li, XU Yu-peng, TIAN Gao-you(褚小立,许育鹏,田高友,译). Practical Guide to Interpretive Near-Infrared Spectroscopy(近红外光谱解析实用指南). Beijing:Chemical Industry Press(北京:化学工业出版社),2009. 10.
[10] XIU Lian-cun, ZHENG Zhi-zhong, YU Zheng-kui, et al(修连存, 郑志忠, 俞正奎, 等). Acta Geologica Sinica(地质学报), 2007, 81(11): 1584.
[11] BAI Li-xin (白立新). Ningxia Engineering Technology(宁夏工程技术), 2007, 6(4): 224.
[12] ZHANG Zong-gui, WANG Run-sheng, GUO Xiao-fang, et al(张宗贵, 王润生, 郭小方, 等). Earth Science Frontier(地学前缘), 2003, 10(2): 437.
[13] YANG Zhi-ming, HOU Zeng-qian, YANG Zhu-sen, et al(杨志明, 侯增谦, 杨竹森, 等). Mineral Deposits(矿床地质), 2012, 31(4): 699.
[14] Cao J, Hu X, Jiang Z, et al. Geofluids, 2010, 10(3): 438.
[15] Cao J, Li Y, Jiang T, et al. Atmospheric Chemistry and Physics, 2015, 15(12): 6959. |
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