Fluid origins and ages of Au mineralization of the Hosen 8-2 vein, Hishikari deposit, Kagoshima, Japan

IF 3.4 2区 地球科学 Q1 GEOCHEMISTRY & GEOPHYSICS
Jonathan Macuroy , Ryohei Takahashi , Akira Hara , Yoshinori Okaue , Akira Imai , Pearlyn Manalo , Hinako Sato , Andrea Agangi
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Abstract

The oxygen and hydrogen isotope ratios of ore-forming fluids and formation ages were determined using quartz, adularia, and clay minerals in the Hosen 8-2 vein at −5 ML of the Hishikari deposit. Electrum, the dominant ore mineral, is found exclusively in the early band composed of microcrystalline quartz, granular adularia, and smectite. A relatively low Au-grade zone with Au grades below 100 ppm is identified in the southwestern part of the vein, while a ∼25-meter-wide bonanza zone with Au grades up to 10,800 ppm was identified in the central part. The northeastern part of the vein is referred to as the high Au-grade zone, with Au grades between 100 and 1000 ppm.
The calculated fluid δ18O values of the bonanza and high Au-grade zones calculated from quartz in the Hosen 8-2 vein are heterogenous (−6.3 to −0.8 ‰, and −6.8 to −2.9 ‰, respectively). This wide variation indicates the association of the mineralized zones with the boiling zone of upwelling deep fluids and the subsequent mixing with shallow meteoric water, which can be a useful vector of highly mineralized zones in the Hishikari deposit. Conversely, the low Au-grade zone is characterized by lower and more homogenous calculated fluid δ18O values (−5.2 to −4.0 ‰) that are closer to the isotopic composition of meteoric water.
The fluids that precipitated electrum and clay minerals have high δ18O values (+3.0 to +7.6 ‰) and low δD values (−132 to −100 ‰), which can be caused by the interaction between deeply circulating meteoric water and the sedimentary rocks of the Shimanto Supergroup at temperatures about 200–350 °C. It is also possible that δD values below −100 ‰ reflect contributions from waters released from Fe-poor hydrous sheet silicates in the host rocks.
The δ18O values of fluids calculated from adularia that formed after the early clay band range from −2.9 to +1.2 ‰. The progressive decrease of the fluid δ18O values across the paragenetic sequence can be attributed to the influx of 18O-depleted meteoric waters that mixed with Au-bearing 18O-enriched deep fluids.
The calculated fluid δD values of mixed smectite, illite, and interstratified chlorite-smectite from the altered host rock are much higher (−87 to −57 ‰) than those of the clays from the vein, although their fluid δ18O values are relatively similar (−0.3 to +10.2 ‰). These values indicate that the clays from the altered host rock may have originated from the water-rock interaction between shallow fluids and the volcanic rocks of the Hishikari Lower Andesites.
40Ar/39Ar dating of four adularia separates from the Hosen 8-2 vein yielded plateau ages from 0.930 ± 0.002 to 0.945 ± 0.001 Ma. The crystallization age of the low Au-grade zone (0.930 ± 0.002 Ma) overlaps within error with that of the bonanza zone (0.932 ± 0.002 Ma), suggesting roughly similar ages that is in contrast with their distinctly different Au grades. The high Au-grade zone formed from 0.945 ± 0.001 to 0.938 ± 0.003 Ma.
日本鹿儿岛Hishikari矿床Hosen 8-2矿脉金矿化的流体起源和年龄
利用位于 Hishikari 矿床 -5 ML 的 Hosen 8-2 矿脉中的石英、金刚砂和粘土矿物,测定了成矿流体的氧和氢同位素比率以及形成年龄。主要矿石矿物--电解铝只存在于由微晶石英、粒状金刚砂和粘土矿组成的早期带中。在矿脉的西南部发现了一个金品位相对较低的区域,金品位低于 100 ppm,而在中部发现了一个 25 米宽的金矿带,金品位高达 10 800 ppm。根据霍森 8-2 矿脉中的石英计算出的砾岩带和高金品位带的流体δ18O 值是不同的(分别为-6.3 至-0.8 ‰和-6.8 至-2.9 ‰)。这种巨大的差异表明矿化带与上涌深层流体的沸腾带有关,随后与浅层陨石水混合,这可能是 Hishikari 矿床中高矿化带的有用载体。相反,低金品位区的特点是计算出的流体δ18O值(-5.2 至 -4.0‰)较低且更均匀,更接近陨水的同位素组成。沉淀出电解质和粘土矿物的流体具有较高的δ18O值(+3.沉淀出电解质和粘土矿物的流体具有较高的δ18O 值(+3.0 至 +7.6 ‰)和较低的δD 值(-132 至 -100‰),这可能是由于深层循环的陨石水与谛听超群的沉积岩在约 200-350 ℃的温度下相互作用造成的。δD值低于-100‰也有可能反映了寄主岩中贫铁水合片硅酸盐释放的水的贡献。从早期粘土带之后形成的金刚砂中计算出的流体δ18O值在-2.9‰到+1.2‰之间。流体δ18O值在整个成因序列中逐渐降低,这可能是由于贫18O的陨石水与含金18O富集的深层流体混合后流入。来自蚀变主岩的混合闪长岩、伊利石和层间绿泥石-闪长岩的计算流体δD值(-87至-57‰)远高于来自矿脉的粘土,尽管它们的流体δ18O值相对相似(-0.3至+10.2‰)。这些数值表明,来自蚀变主岩的粘土可能源自浅层流体与 Hishikari 下安山岩的火山岩之间的水岩相互作用。40Ar/39Ar 测定对来自 Hosen 8-2 矿脉的四块金刚砂分离物进行了测年,得出的高原年龄为 0.930 ± 0.002 至 0.945 ± 0.001 Ma。低金矿品位区的结晶年龄(0.930 ± 0.002 Ma)与金矿区的结晶年龄(0.932 ± 0.002 Ma)在误差范围内重叠,表明两者的年龄大致相似,但金矿品位却截然不同。高金品位区形成于 0.945 ± 0.001 至 0.938 ± 0.003 Ma 之间。
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来源期刊
Journal of Geochemical Exploration
Journal of Geochemical Exploration 地学-地球化学与地球物理
CiteScore
7.40
自引率
7.70%
发文量
148
审稿时长
8.1 months
期刊介绍: Journal of Geochemical Exploration is mostly dedicated to publication of original studies in exploration and environmental geochemistry and related topics. Contributions considered of prevalent interest for the journal include researches based on the application of innovative methods to: define the genesis and the evolution of mineral deposits including transfer of elements in large-scale mineralized areas. analyze complex systems at the boundaries between bio-geochemistry, metal transport and mineral accumulation. evaluate effects of historical mining activities on the surface environment. trace pollutant sources and define their fate and transport models in the near-surface and surface environments involving solid, fluid and aerial matrices. assess and quantify natural and technogenic radioactivity in the environment. determine geochemical anomalies and set baseline reference values using compositional data analysis, multivariate statistics and geo-spatial analysis. assess the impacts of anthropogenic contamination on ecosystems and human health at local and regional scale to prioritize and classify risks through deterministic and stochastic approaches. Papers dedicated to the presentation of newly developed methods in analytical geochemistry to be applied in the field or in laboratory are also within the topics of interest for the journal.
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