| China Geological Survey Chinese Academy of Geological Sciences | Host |
| 科学出版社 | Publish |
| Citation: |
ZHAO Hongjun, CHEN Xiufa, HE Xuezhou, ZHANG Xinyuan, ZHANG Chao, WANG Liangliang, CHEN Yuming, CHEN Xifeng, LU Minjie, ZHOU Shangguo, HUANG Feixin, YAO Chunyan, YANG Yanchen. 2018. A study of genetic type characteristics and important distribution zones of global iron deposits[J]. Geology in China, 45(5): 890-919. doi: 10.12029/gc20180502
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A study of genetic type characteristics and important distribution zones of global iron deposits
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Abstract
China is the world's largest consumer of iron ore. The annual import of iron ore has exceeded 900 million tons, and its imports exceed 60% of the global iron ore trade volume. The summarization and potential analysis of global iron ore type characteristics and important distribution zones are of important theoretical and practical significance. This paper sums up the endowment characteristics of global iron ore resources. The authors divide global iron deposits into five genetic types:BIF-related, sedimentary, volcanic, magmatic, and contact-hydrothermal (skarn) deposits, with the emphasis placed on the analysis of geological characteristics of BIF-related and volcanic iron ore deposits as well as genesis and prospecting indicators. According to the comprehensive factors such as tectonic units, stratigraphic sequence, ore-bearing structure characteristics, deposit types and metallogenic ages of iron ore deposits, a total of 33 iron ore distribution areas and 47 important distribution belts of iron ore deposits are delineated in the major geotectonic units of the world. In addition, the resource potential of each important distribution belt is discussed.
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References
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ZHAO Hongjun, CHEN Xiufa, HE Xuezhou, ZHANG Xinyuan, ZHANG Chao, WANG Liangliang, CHEN Yuming, CHEN Xifeng, LU Minjie, ZHOU Shangguo, HUANG Feixin, YAO Chunyan, YANG Yanchen. 2018. A study of genetic type characteristics and important distribution zones of global iron deposits[J]. Geology in China, 45(5): 890-919. doi: 10.12029/gc20180502
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Figure 1.
Growth rate and foreign dependence of China's imported iron ore since 2000
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Figure 2.
Average grade of iron ore in the world's major iron ore production countries (modified after USGS, 2015; Lisha, 2017)
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Figure 3.
BIF-related iron deposit distribution map
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Figure 4.
Schematic diagram showing the relationship between the formation time of IF and its development degree (abundance), including some significant IF and major IF regions (modified after Trendall 2002 and Klein, 2005)
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Figure 5.
Sketch map of sedimentary environment of BIF and GIF (modified after Wang et al., 2009 and Bekker et al., 2010)
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Figure 6.
Sketch geological map of the major iron orebodies in the Hamersley iron province (after Taylor et al., 2001) and stratigraphic columnar section of the Hamersley iron province and available SHRIMP ages (after Barley et al., 1997)
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Figure 7.
Simplified geological map of the Quadrilatero Ferrifero (after Zhao Hongjun et al, 2017)
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Figure 8.
Schematic map of magnetic anomalies in the Kursk magnetic anomaly zone and lithofacies zoning of the iron-bearing quartzite series (after Institute of Information Standards, Ministry of Metallurgy, 1975)
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Figure 9.
Distribution of volcanic iron deposits
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Figure 10.
Ideal modal map for the porphyritic iron deposits (after Research Group of the Ning-Wu Project, 1978)
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Figure 11.
Global important iron ore distribution map (The serial number in the diagram is consistent with the iron ore distribution zone number in Table 5)