Abstract
Previous geochemical and petrological studies have concluded that initially magmatic Nb–Ta mineralization is often modified by post-magmatic hydrothermal fluids; however, there is still a lack of mineralogical evidence for the syenite-related Nb–Ta deposit. From the perspective of Nb–Ta minerals, the pyrochlore supergroup minerals have significance for indicating the fluid evolution of alkaline rock or related carbonatite type Nb–Ta deposits. The Panzhihua–Xichang (Panxi) region is a famous polymetallic metallogenic belt in southwestern China, abound with a huge amount of Nb–Ta mineralized syenitic dikes. This study focuses on the mineral textures and chemical compositions of the main Nb–Ta oxide minerals (including columbite-(Fe), fersmite, fergusonite-(Y), and especially pyrochlore group minerals) in samples from the Baicao and Xiaoheiqing deposits, in the Huili area, Panxi region, to reveal the magma evolution process of syenitic-dike-related Nb–Ta deposits. The Nb–Ta oxides in the Huili syenites are commonly characterized by a specific two-stage texture on the crystal scale, exhibiting a complex metasomatic structure and compositional zoning. Four types of pyrochlore group minerals (pyrochlores I, II, III, and IV) formed in different stages were identified. The euhedral columbite-(Fe), fersmite, and pyrochlores I and II minerals formed in the magmatic fractional crystallization stage. Anhedral pyrochlore III minerals are linked to the activity of magma-derived hydrothermal fluids at the late stages of magma evolution. The pyrochlore IV minerals and fergusonite-(Y) tend to be more concentrated in areas that have undergone strong albitization, which is a typical phenomenon of hydrothermal alteration. These mineralogical phenomena provide strong evidences that the magmatic-hydrothermal transitional stage is the favored model for explaining the Nb–Ta mineralization process. It is also concluded that the changes in chemical composition and texture characteristics for pyrochlore group minerals could serve as a proxy for syenite-related Nb–Ta mineralization processes.
Highlights
Most economically significant magmatic Nb deposits are associated with either carbonatites or felsic igneous rocks [1]
As is shown in the back-scattered electron (BSE) images, the columbite-(Fe) forms anhedral to subhedral crystals, which are disseminated in albite, biotite, and calcite, are intergrown with fersmite, and are up to 100 μm in diameter (Figure 5a,b)
The pyrochlore group minerals formed in the primary magma stage exhibit the characteristics of magmatic fractional crystallization
Summary
Most economically significant magmatic Nb deposits are associated with either carbonatites or felsic igneous rocks [1]. Felsic igneous rocks include nepheline syenites, A-type granites and syenites [4,5,6], and related pegmatites [7,8,9]. One view holds that Nb–Ta mineralization is the product of magmatic crystallization processes. This view is based on experimental data [9,10,11,12] and natural samples [13,14,15,16,17,18], which have shown that the enrichment of rare elements occurs during the fractionation of granitic melts.
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