| China Geological Survey Chinese Academy of Geological Sciences | Host |
| 科学出版社 | Publish |
| Citation: |
SONG Zhe, LI Houmin, LI Lixing, DING Jianhua, MENG Jie. 2020. Magnetite compositions of the iron-rich agglomerates of the Heijianshan iron deposit in Eastern Tianshan Mountains and magmatic-hydrothermal evolution processes[J]. Geology in China, 47(3): 590-606. doi: 10.12029/gc20200303
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Magnetite compositions of the iron-rich agglomerates of the Heijianshan iron deposit in Eastern Tianshan Mountains and magmatic-hydrothermal evolution processes
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Abstract
The Heijianshan iron deposit represents a typical submarine volcanic rock-hosted deposit of the Aqishan-Yamansu ore belt in Eastern Tianshan Mountains. Abundant irregular iron-rich agglomerates are developed in the brecciated andesite lava (wall rock), and they can be subdivided into five types, i.e., albite-magnetite type, albite-K-feldspar magnetite type, K-feldsparmagnetite type, epidote-magnetite type and quartz-magnetite type, likely representing evolving products of the magmatic-hydrothermal ore-forming process, which can constrain the ore-forming process and metallogenic environment of the Heijianshan iron deposit. Magnetite compositions of the five types of agglomerates were analyzed using electron microprobe analysis. For the purpose of obtaining precise Fe content, the content of undetermined O was added by difference method and the ZAF matrix correction was conducted. The Ti values of the five types of agglomerates display a positive relationship with the Fe values. Magnetite of the albite-magnetite type has highest Ti content, the albite-K-feldspar magnetite and the K-feldspar-magnetite types show medium Ti content, whereas the epidote-magnetite and quartz-magnetite types are characterized by the lowest Ti content. Also, the Fe content of the epidote-magnetite and the quartz-magnetite types is similar to that of the ores. These features indicate that the albite-magnetite type seems to have been the earliest crystallization product from a residual iron-rich melt, the albite-K-feldspar-magnetite and K-feldspar-magnetite types display features of magmatic-hydrothermal transition, whereas the epidote-magnetite and quartz-magnetite types represent products of hydrothermal alteration. The Fe content of magnetite of each type of agglomerate is higher than its content of the corresponding alteration zone, suggesting a simultaneous relationship between the crystallization of iron-rich agglomerates and hydrothermal activities.
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References
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SONG Zhe, LI Houmin, LI Lixing, DING Jianhua, MENG Jie. 2020. Magnetite compositions of the iron-rich agglomerates of the Heijianshan iron deposit in Eastern Tianshan Mountains and magmatic-hydrothermal evolution processes[J]. Geology in China, 47(3): 590-606. doi: 10.12029/gc20200303
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Figure 1.
Tectonic framework in the Eastern Tianshan orogenic belt and distribution of iron ore deposits in Aaqishan-Yamansu backarc basin (modified from Qin Kezhang et al., 2003)
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Figure 2.
Geological map of the Heijianshan iron deposit (modified from Xinjiang Uygur Autonomous Region Geological Survey, 2003 and Zhao Liandang et al., 2017)
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Figure 3.
Photographs and photomicrographs illustrating the features of the albite-magnetite type iron-rich agglomerates
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Figure 4.
Photographs and photomicrographs illustrating the features of the albite-K-feldspar-magnetite type iron-rich agglomerates
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Figure 5.
Photographs and photomicrographs illustrating the features of the K-feldspar-magnetite type iron-rich agglomerates
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Figure 6.
Photographs and photomicrographs illustrating the features of the epidote-magnetite type iron-rich agglomerates
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Figure 7.
Photographs and photomicrographs illustrating the features of the quartz-magnetite type iron-rich agglomerates
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Figure 8.
Characteristics of iron-rich agglomerates in the Heijianshan deposit by electron microprobe analysis (backscatter microscopic imaging)
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Figure 9.
Multi-element diagram for the magnetite of iron-rich agglomerates in the Heijianshan deposit
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Figure 10.
Comparison of magnetite compositions between magnetite in iron-rich agglomerates and ore in the Heijianshan deposit
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Figure 11.
Comparison of magnetite compositions in iron-rich agglomerates of the Heijianshan iron deposit and in iron-rich fragments of the Yamansu iron deposit