{"title":"纽芬兰-阿巴拉契亚山脉垫层带火山成因块状硫化物矿床:背景、类型、关键进展和未来研究","authors":"Stephen J. Piercey, John Hinchey, Greg W. Sparkes","doi":"10.1139/cjes-2022-0148","DOIUrl":null,"url":null,"abstract":"The Dunnage Zone of the Newfoundland Appalachians hosts diverse Cambrian–Ordovician volcanogenic massive sulfide (VMS) deposits. The peri-Laurentian Notre Dame Subzone contains Cu–Zn–Au mafic and bimodal mafic deposits in ∼501–485 Ma ophiolitic rocks and Zn–Pb–Cu–(Au–Ag) deposits in ∼471–465 Ma bimodal rifted continental arc sequences (e.g., Buchans). The peri-Gondwanan rocks of the Exploits Subzone host Zn–Pb–Cu–(Au–Ag) bimodal felsic, felsic siliciclastic, and Zn–Ag–Au hybrid bimodal felsic deposits in the ∼513–486 Ma Victoria Lake supergroup; Cu–Zn bimodal felsic to bimodal mafic deposits of the ∼486 Ma Wild Bight Group; and Cu–(Au) mafic siliciclastic deposits of the ∼466 Ma Great Burnt Lake/South Pond belt. Regardless of age or stratigraphic hosts, all VMS deposits are associated with specific magmatic assemblages and extensional tectonism (i.e., rifting). Gold-enriched deposits of the Rambler-Ming district are associated with felsic rocks that formed via slab melting and subsequent melt-mantle wedge interaction, which likely enhanced precious metal enrichment in these deposits. Whereas many deposits exhaled on the seafloor, some deposits formed via subseafloor replacement of host units or as re-sedimented sulfides generated in sediment-gravity flows. Metals in the deposits were derived from leaching of underlying footwall rocks; however, Au–Ag- and epithermal suite element-enriched deposits show evidence for metal contributions from magmatic hydrothermal fluids. Sulfur in deposits was derived predominantly from leaching of H 2 S from underlying footwall rocks and from thermochemical sulfate reduction of seawater sulfate, with lesser input from bacteria-derived H 2 S and magmatic-hydrothermal-derived H 2 S. Despite recent research advances and historic mining, numerous questions remain unresolved and provide opportunities for future study.","PeriodicalId":9567,"journal":{"name":"Canadian Journal of Earth Sciences","volume":"14 1","pages":"0"},"PeriodicalIF":1.3000,"publicationDate":"2023-08-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Volcanogenic massive sulfide (VMS) deposits of the Dunnage Zone of the Newfoundland Appalachians: setting, styles, key advances, and future research\",\"authors\":\"Stephen J. Piercey, John Hinchey, Greg W. 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Gold-enriched deposits of the Rambler-Ming district are associated with felsic rocks that formed via slab melting and subsequent melt-mantle wedge interaction, which likely enhanced precious metal enrichment in these deposits. Whereas many deposits exhaled on the seafloor, some deposits formed via subseafloor replacement of host units or as re-sedimented sulfides generated in sediment-gravity flows. Metals in the deposits were derived from leaching of underlying footwall rocks; however, Au–Ag- and epithermal suite element-enriched deposits show evidence for metal contributions from magmatic hydrothermal fluids. Sulfur in deposits was derived predominantly from leaching of H 2 S from underlying footwall rocks and from thermochemical sulfate reduction of seawater sulfate, with lesser input from bacteria-derived H 2 S and magmatic-hydrothermal-derived H 2 S. 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引用次数: 0
摘要
纽芬兰-阿巴拉契亚的垫层带拥有多种寒武纪-奥陶系火山块状硫化物矿床。约laurentian Notre Dame亚带包含~ 501-485 Ma蛇绿岩中的Cu-Zn-Au基性和双峰基性矿床,以及~ 471-465 Ma双峰裂陷大陆弧序列(如Buchans)中的Zn-Pb-Cu - (Au-Ag)矿床。在~ 513-486 Ma维多利亚湖超群中,发育Zn-Pb-Cu - (Au-Ag)双峰长英质、长英质硅塑性和Zn-Ag-Au混合双峰长英质矿床;~ 486 Ma Wild Bight群Cu-Zn双峰长晶-双峰镁铁质矿床~ 466 Ma Great burn Lake/South Pond带的Cu - (Au)基性硅质碎屑矿床。无论年龄或地层寄主如何,所有VMS矿床都与特定的岩浆组合和伸展构造(即裂陷)有关。Rambler-Ming地区的富金矿床与长英质岩有关,长英质岩是通过板块熔融和随后的熔融-地幔楔体相互作用形成的,可能增强了这些金矿床的贵金属富集。虽然许多沉积物在海底呼出,但有些沉积物是通过海底替换宿主单元或作为沉积物重力流产生的再沉积硫化物而形成的。矿床中的金属来源于下伏下盘岩石的浸出;而富含Au-Ag和浅成热液组元素的矿床显示岩浆热液对金属的贡献。矿床中的硫主要来自下伏下盘岩石的h2s浸出和海水硫酸盐的热化学硫酸盐还原,细菌衍生的h2s和岩浆热液衍生的h2s的输入较少。尽管最近的研究进展和历史采矿,许多问题仍未解决,并为未来的研究提供了机会。
Volcanogenic massive sulfide (VMS) deposits of the Dunnage Zone of the Newfoundland Appalachians: setting, styles, key advances, and future research
The Dunnage Zone of the Newfoundland Appalachians hosts diverse Cambrian–Ordovician volcanogenic massive sulfide (VMS) deposits. The peri-Laurentian Notre Dame Subzone contains Cu–Zn–Au mafic and bimodal mafic deposits in ∼501–485 Ma ophiolitic rocks and Zn–Pb–Cu–(Au–Ag) deposits in ∼471–465 Ma bimodal rifted continental arc sequences (e.g., Buchans). The peri-Gondwanan rocks of the Exploits Subzone host Zn–Pb–Cu–(Au–Ag) bimodal felsic, felsic siliciclastic, and Zn–Ag–Au hybrid bimodal felsic deposits in the ∼513–486 Ma Victoria Lake supergroup; Cu–Zn bimodal felsic to bimodal mafic deposits of the ∼486 Ma Wild Bight Group; and Cu–(Au) mafic siliciclastic deposits of the ∼466 Ma Great Burnt Lake/South Pond belt. Regardless of age or stratigraphic hosts, all VMS deposits are associated with specific magmatic assemblages and extensional tectonism (i.e., rifting). Gold-enriched deposits of the Rambler-Ming district are associated with felsic rocks that formed via slab melting and subsequent melt-mantle wedge interaction, which likely enhanced precious metal enrichment in these deposits. Whereas many deposits exhaled on the seafloor, some deposits formed via subseafloor replacement of host units or as re-sedimented sulfides generated in sediment-gravity flows. Metals in the deposits were derived from leaching of underlying footwall rocks; however, Au–Ag- and epithermal suite element-enriched deposits show evidence for metal contributions from magmatic hydrothermal fluids. Sulfur in deposits was derived predominantly from leaching of H 2 S from underlying footwall rocks and from thermochemical sulfate reduction of seawater sulfate, with lesser input from bacteria-derived H 2 S and magmatic-hydrothermal-derived H 2 S. Despite recent research advances and historic mining, numerous questions remain unresolved and provide opportunities for future study.
期刊介绍:
The Canadian Journal of Earth Sciences reports current research in climate and environmental geoscience; geoarchaeology and forensic geoscience; geochronology and geochemistry; geophysics; GIS and geomatics; hydrology; mineralogy and petrology; mining and engineering geology; ore deposits and economic geology; paleontology, petroleum geology and basin analysis; physical geography and Quaternary geoscience; planetary geoscience; sedimentology and stratigraphy; soil sciences; and structural geology and tectonics. It also publishes special issues that focus on information and studies about a particular segment of earth sciences.