Chemical Mapping of Trace Elements in Pyrite Provides Insight into Mineralizing Processes: the Example of the Neoarchean Cu–Au Porphyry System of the Chibougamau Area, Canada

IF 0.8 4区 地球科学 Q3 GEOLOGY
Lucie Mathieu, Dany Savard, Andrey Kulynych-Rinta
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Abstract

Archean porphyry-style mineralization is one of the sources of Au and Cu in greenstone belts. Archean porphyries have been modified by regional deformation and late fluid circulation, and questions remain on the timing of Au mineralization. Indeed, Au may have been introduced at the magmatic-hydrothermal (porphyry) stage, or by a post-magmatic hydrothermal fluid (overprinting orogenic gold system), or a combination of these two processes. Using the Cu–Au Corner Bay deposit as a case study and high-quality chemical mapping performed using laser ablation coupled to a time-of-flight mass spectrometer (LA-FF-ICP-ToF-MS), this study demonstrates that pyrite chemistry has the potential to reconstitute the metallogenic model for Archean porphyry systems. The Corner Bay deposit is associated with the ~2718–2715 Ma Chibougamau pluton, located in the northeastern corner of the gold-endowed Abitibi greenstone belt. Pyrite chemistry points to the following succession of events at Corner Bay: (1) an early porphyry stage that produced pyrite-mineralized quartz-anhydrite veins associated to chloritization and sericitization; (2) followed by a porphyry stage that includes brecciation in response to fluid overpressure and deposition of Cu-Au mineralization by magmatic-hydrothermal fluids with a multi-metal signature (Cu, Ag, Bi, Te, etc.); and (3) a post-porphyry deformation event(s) that induced parallel fracturing and minor carbonatization. This study proposes that, at Corner Bay, Au was introduced during the porphyry-stage of mineralization and was neither remobilized, nor further introduced, during the ~2700 Ma regional deformation stage that is coeval with most orogenic gold-style of mineralization in the southern part of the Abitibi greenstone belt.

Abstract Image

黄铁矿中微量元素的化学成分图揭示成矿过程:以加拿大 Chibougamau 地区的新元古代铜金矿斑岩系统为例
摘要 阿歇安斑岩型矿化是绿岩带金和铜的来源之一。由于区域变形和晚期流体循环对阿尔奇岩斑岩进行了改造,金矿化的时间仍然存在疑问。事实上,金可能是在岩浆-热液(斑岩)阶段引入的,也可能是由岩浆后热液流体(叠加造山金系统)引入的,或者是这两个过程的结合。本研究以角湾铜金矿床为案例,利用激光烧蚀耦合飞行时间质谱仪(LA-FF-ICP-ToF-MS)绘制了高质量的化学图谱,证明黄铁矿化学有可能重建阿歇安斑岩系统的成矿模式。Corner Bay矿床与约2718-2715Ma的Chibougamau岩体有关,该岩体位于蕴藏金矿的阿比提比绿岩带的东北角。黄铁矿化学成分表明 Corner Bay 发生了以下事件:(1) 早期斑岩阶段产生了黄铁矿化的石英-软玉矿脉,并伴有绿泥石化和绢云母化;(2) 随后是斑岩阶段,包括流体超压引起的角砾岩化,以及岩浆-热液造成的铜-金矿化沉积,具有多金属特征(铜、银、铋、碲等);(3) 后斑岩阶段,包括流体超压引起的角砾岩化,以及岩浆-热液造成的铜-金矿化沉积,具有多金属特征(铜、银、铋、碲等)。3)斑岩后变形事件,诱发平行断裂和轻微碳酸盐化。本研究认为,在 Corner Bay,金是在斑岩成矿阶段引入的,在与阿比提比绿岩带南部大多数造山型金矿成矿同时发生的 ~2700 Ma 区域变形阶段,金既没有被重新移动,也没有被进一步引入。
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来源期刊
Geology of Ore Deposits
Geology of Ore Deposits 地学-地质学
CiteScore
1.10
自引率
14.30%
发文量
24
审稿时长
6-12 weeks
期刊介绍: Geology of Ore Deposits is a periodical covering the topic of metallic and nonmetallic mineral deposits, their formation conditions, and spatial and temporal distribution. The journal publishes original scientific articles and reviews on a wide range of problems in theoretical and applied geology. The journal focuses on the following problems: deep geological structure and geodynamic environment of ore formation; distribution pattern of metallogenic zones and mineral deposits; geology and formation environment of large and unique metallic and nonmetallic deposits; mineralogy of metallic and nonmetallic deposits; physicochemical and isotopic characteristics and geochemical environment of ore deposition; evolution of ore-forming systems; radiogeology and radioecology, economic problems in exploring, developing, and mining of ore commodities.
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