An update on skarn deposits of Alaska

Newberry, R. J.

doi:10.14509/1699

Cited by 2 publications

(7 citation statements)

References 9 publications

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“…The scheelite at Xiaoyao has a wide range of WO 3 Figure 6a). [30], the Jitoushan and Baizhangya tungsten deposits [9], the King-Island-oxidized skarn deposit [17], the Kara-oxidized skarn deposit [31], and the Los-Santos-reduced skarn deposit [32]. [30], the Jitoushan and Baizhangya tungsten deposits [9], the King-Island-oxidized skarn deposit [17], the Kara-oxidized skarn deposit [31], and the Los-Santos-reduced skarn deposit [32].…”

Section: Major Element Geochemistrymentioning

confidence: 99%

“…Sch1b in the distal zone has lower MoO 3 contents of 0.38-0.42% ( Table 2 and Figure 8B). The carbonaceous wall rocks may lessen the effects of such a relatively oxidized magma [17,18]. However, the lack of association between molybdenite and Sch1b under reduced conditions suggests that the ore solution may be already depleted in molybdenum and/or under low f S 2 conditions [34].…”

Section: Oxidation State Of Ore-forming Fluidsmentioning

confidence: 99%

“…The late oxidized Mo-rich granodiorite dike overprints the sample location of Sch2b (Figure 3), and Sch2b and Sch3 have the same REE patterns with ore-related granodiorite (Figure 7d,f). The elevated Mo content may be provided by the high oxidation state, as well as an overprinting or remobilization of the oxidized Mo-rich magmatic-hydrothermal system [17]. However, Sch2a and Sch4 have low MoO 3 contents (1.71-3.51% and 0.19-0.76%, respectively), accompanied by MoS 2 precipitation ( Figure 8C,H).…”

Section: Oxidation State Of Ore-forming Fluidsmentioning

confidence: 99%

“…The replacement of garnet released large amounts of calcium ion into the ore-forming fluid and thus raised the activity of calcium ion in solution. Consequently, this led to a disequilibrium between precipitated scheelite and evolving fluids [16,17]. In addition, the W contents of garnet from the Xiaoyao deposit are [9], Xitian [38]; the reduced tungsten skarn deposits, including the Zhuxi [15], Xianglushan [14], Kyanigan [39].…”

Section: Dissolution and Re-precipitationmentioning

confidence: 99%

“…Despite the extensive literature on trace elements in scheelite, only a few studies focus on tungsten skarn deposits [12][13][14][15]. Most tungsten skarn deposits are characterized by multiple scheelite generations which underwent dissolution and re-precipitation processes [16][17][18]. The superimposition of multiple scheelite generations complicates study on the ore-forming processes via the trace element chemistry of scheelite.…”

Section: Introductionmentioning

confidence: 99%

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Geochemistry and Origin of Scheelites from the Xiaoyao Tungsten Skarn Deposit in the Jiangnan Tungsten Belt, SE China

Mao

Sun

et al. 2020

Minerals

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The type, association, variations, and valence states of several metal elements of scheelite can trace the source and evolution of the ore-forming fluids. There are four types of scheelite from the Xiaoyao deposit: (1) scheelite intergrown with garnet in the proximal zone (Sch1a) and with pyroxene in the distal zone (Sch1b), (2) scheelite replaced Sch1a (Sch2a) and crystallized as rims around Sch1b (Sch2b), (3) quartz vein scheelite with oscillatory zoning (Sch3), and 4) scheelite (Sch4) within micro-fractures of Sch3. Substitutions involving Mo and Cd are of particular relevance, and both elements are redox-sensitive and oxidized Sch1a, Sch2b, Sch3 are Mo and Cd enriched, relatively reduced Sch1b, Sch2a, Sch4 are depleted Mo and Cd. Sch1a, Sch2a, Sch3, and Sch4 are characterized by a typical right-inclined rare earth element (REE) pattern, inherited from ore-related granodiorite and modified by the precipitation of skarn minerals. Sch1b and Sch2b are characterized by low light rare earth element/heavy rare earth element (LREE/HREE) ratios, influenced by a shift in fO 2 during fluid-rock alteration. Sch1b, Sch2b and Sch3 have higher Sr contents than those of Sch1a and Sch2a, reveal that host-rock alteration and fluid-rock interaction have elevated Sr contents. The Y/Ho ratios of scheelite gradually increase from skarn to quartz vein stages, due to fluid fractionation caused by fluid-rock interaction. Thus, the variation in REE and trace elements in scheelite in time and space reflects a complex magmatic-hydrothermal process involving various fluid-rock interactions and fluid mixing.Minerals 2020, 10, 271 2 of 22 (CL) imaging has been proven to be an effective technique to reveal internal textures, zoning and trace element distributions in scheelite [3]. However, previous studies did not evaluate dissolution and re-precipitation processes in scheelite from tungsten skarn deposits due to the changing hydrothermal fluids [13,14]. The detailed textural characterization and systematic investigations of scheelite from each stage prior to in situ chemical analysis are critical to constraint the evolution of skarn systems and W ore precipitation.The Jiangnan tungsten belt in the southeastern margin of the Yangtze Craton is a new giant tungsten province with WO 3 reserves over 5.0 million tons [19][20][21][22][23], including the Dahutang (reserves of 1.10 Mt and grade of 0.18%) and the Zhuxi (reserves of 3.44 Mt and grade of 0.54%) deposits, as well as other large-scale tungsten deposits, such as Yangchuling, Xiaoyao, Dongyuan, Zhuxiling deposits [24][25][26]. The present study focuses on the Xiaoyao tungsten skarn deposit, characterized by complex scheelite textural features. The Xiaoyao deposit has reserves of 75,000 tons of WO 3 with an average grade of 0.2% [27]. We present both textural and compositional features for scheelite from the Xiaoyao deposit to evaluate the importance of dissolution and re-precipitation processes in the formation of skarn-related scheelite.

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Section: Major Element Geochemistrymentioning

confidence: 99%

Section: Oxidation State Of Ore-forming Fluidsmentioning

confidence: 99%

Section: Oxidation State Of Ore-forming Fluidsmentioning

confidence: 99%

Section: Dissolution and Re-precipitationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Geochemistry and Origin of Scheelites from the Xiaoyao Tungsten Skarn Deposit in the Jiangnan Tungsten Belt, SE China

Mao

Sun

et al. 2020

Minerals

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Evolution of Ore-Forming Fluids at Azegour Mo-Cu-W Skarn Deposit, Western High Atlas, Morocco: Evidence from Mineral Chemistry and Fluid Inclusions

El Khalile,

Aissa,

Touil

et al. 2023

Minerals

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The Azegour Mo-Cu-W skarn deposit, located on the northern side of the Western High Atlas, occurs in lower Cambrian volcanic and sedimentary rocks. The mineralizations are linked to the hydrothermal alterations that affected carbonated layers of the lower Cambrian age during the intrusion of the calc-alkaline hyperaluminous Azegour granite. Four stages of the skarn and ore mineral deposition have been identified as follows. Firstly, (i) the early prograde stage and (ii) the late prograde stage. These prograde stages are characterized by anhydrous minerals (wollastonite, garnets, and pyroxenes) associated with scheelite mineralization. Based on mineral chemistry studies, the early prograde stage is dominated by andradite (Ad72.81–97.07) and diopside (Di61.80–50.08) indicating an oxidized skarn; on the other hand, the late prograde stage is characterized by a high portion of grossular (Gr66.88–93.72) and hedenbergite (Hd50.49–86.73) with a small ratio of almandine (Alm2.84–34.99), indicating “strongly reduced” or “moderately reduced” conditions with low f(O2). The next two stages are (iii) the early retrograde stage and (iv) the late retrograde stage, which contain hydrous minerals (vesuvianite, epidote, chlorite, muscovite, and amphibole) associated with sulfide. Fluid inclusions from pyroxene and quartz (prograde skarn stage) display high homogenization temperatures and high to low salinities (468.3 to >600 °C; 2.1 to >73.9 wt% NaCl equiv.). The boiling process formed major scheelite mineralization during prograde skarn development from dominated hydrothermal magmatic fluid solutions. By contrast, fluid inclusions associated with calcite–quartz–sulfide (retrograde skarn stage) record lower homogenization temperatures and low salinities (160 to 358 °C; 2.0 to 11.9 wt% NaCl equiv.). The distribution of the major inclusions types from the two paragenetic stages are along the trend line of fluids mixing in the salinity–homogenization temperature (magmatic water), illustrating the genesis of ore-forming fluid by mixing with fluids of low temperatures and salinities (metamorphic and meteoric waters).

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An update on skarn deposits of Alaska

Cited by 2 publications

References 9 publications

Geochemistry and Origin of Scheelites from the Xiaoyao Tungsten Skarn Deposit in the Jiangnan Tungsten Belt, SE China

Geochemistry and Origin of Scheelites from the Xiaoyao Tungsten Skarn Deposit in the Jiangnan Tungsten Belt, SE China

Evolution of Ore-Forming Fluids at Azegour Mo-Cu-W Skarn Deposit, Western High Atlas, Morocco: Evidence from Mineral Chemistry and Fluid Inclusions

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