Paul Sotiriou , Ali Polat , Tim Kusky , Brian F. Windley
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The CaO contents of lunar anorthosites are higher than those of early terrestrial anorthosites for a given MgO and Al<sub>2</sub>O<sub>3</sub> <!-->content, early terrestrial anorthosites have higher SiO<sub>2</sub> <!-->contents than lunar anorthosites at a given MgO content, and lunar anorthosites have higher Eu/Eu* anomaly ratios yet broadly similar La/Yb and Nd/Sm ratios than early terrestrial anorthosites. Some early terrestrial anorthosites have less fractionated chondrite-normalised rare earth element (REE) patterns and less prominent positive Eu anomalies than lunar anorthosites. Lunar anorthosites have higher plagioclase An contents, yet a similar range of pyroxene Mg# compared to their early terrestrial counterparts. Some early terrestrial anorthosites<!--> <!-->are more fractionated than some lunar anorthosites. Our interpretations imply that most early terrestrial anorthosites crystallised from basaltic parental magmas that were generated by high-degree partial melting of sub-arc asthenosphere mantle wedge sources that were hydrated by slab-derived fluids, with the remainder being associated with mid-ocean ridge and mantle plume settings. Some of the arc-related early terrestrial anorthosites were influenced by crustal contamination. In addition, early terrestrial anorthosites originated from partial melting of the mantle at various depths with variable garnet residua, whereas lunar anorthosites formed without any significant garnet residua. Lower plagioclase CaO contents and pyroxene Mg# in early terrestrial anorthosites can be explained by higher proportions of clinopyroxene and olivine fractionation in terrestrial magma chambers than in the lunar magma ocean where orthopyroxene and olivine fractionation occurred. Low TiO<sub>2</sub> <!-->contents in both terrestrial and lunar anorthosites reflect rutile and/or ilmenite fractionation.</p></div>","PeriodicalId":12711,"journal":{"name":"Geoscience frontiers","volume":"15 6","pages":"Article 101914"},"PeriodicalIF":8.5000,"publicationDate":"2024-08-20","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://www.sciencedirect.com/science/article/pii/S1674987124001385/pdfft?md5=40675b3ca1a8a50e52468f3b5f055d92&pid=1-s2.0-S1674987124001385-main.pdf","citationCount":"0","resultStr":"{\"title\":\"Early terrestrial and lunar anorthosites: Comparative geochemistry and evolutionary processes\",\"authors\":\"Paul Sotiriou , Ali Polat , Tim Kusky , Brian F. 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引用次数: 0
摘要
布莱恩-温德利(Brian Windley)在 1970 年的一篇论文中首次指出,早期陆地和月球正长岩都具有钙斜长石、低 TiO2 含量、高 CaO 和 Al2O3 含量。尽管存在这些相似之处,但早期陆地和月球正长岩的地球化学还没有进行过严格的比较和对比。为此,我们汇编了 212 个早期陆地正长岩矿点的 425 项分析结果和 16 个月球正长岩矿点的 306 项分析结果。此外,我们还汇编了早期陆地和月球正长岩的斜长石正长石(An)含量和辉石 Mg#。早期陆地正长岩的全岩 An 含量较低,但 Mg# 与月球正长岩相似。在氧化镁和氧化铝含量一定的情况下,月球正长岩的氧化钙含量高于早期陆地正长岩;在氧化镁含量一定的情况下,早期陆地正长岩的二氧化硅含量高于月球正长岩;月球正长岩的Eu/Eu*异常比高于早期陆地正长岩,但La/Yb和Nd/Sm比大致相似。与月球正长岩相比,一些早期陆地正长岩的稀土元素(REE)模式分馏程度较低,正Eu异常也不那么突出。与早期陆地正长岩相比,月球正长岩的斜长石An含量较高,但辉石Mg#的范围相似。与某些月球正长岩相比,某些早期陆地正长岩的分馏程度更高。我们的解释意味着,大多数早期陆地正长岩是由玄武质母岩结晶而成的,这些母岩是由弧下天体层地幔楔源的高度部分熔融产生的,并被板块衍生流体水化,其余的则与洋中脊和地幔羽流环境有关。一些与弧有关的早期陆地正长岩受到地壳污染的影响。此外,早期陆地正长岩源于地幔在不同深度的部分熔化,其石榴石残留物各不相同,而月球正长岩的形成则没有任何明显的石榴石残留物。早期陆地正长岩中斜长石 CaO 含量和辉石 Mg# 含量较低的原因是陆地岩浆室中的挛辉石和橄榄石分馏比例高于月球岩浆洋中的正长石和橄榄石分馏比例。陆相和月相正长岩中较低的二氧化钛含量反映了金红石和/或钛铁矿的分馏。
Early terrestrial and lunar anorthosites: Comparative geochemistry and evolutionary processes
In a paper in 1970, Brian Windley first recognised that early terrestrial and lunar anorthosites both have calcic plagioclase, and low TiO2 and high CaO and Al2O3 contents. Despite these similarities, the geochemistry of early terrestrial and lunar anorthosites has not been rigorously compared and contrasted. To this end, we compiled 425 analyses from 212 early terrestrial anorthosite occurrences and 306 analyses from 16 lunar anorthosite occurrences. This was supplemented by a compilation of plagioclase anorthite (An) contents and pyroxene Mg# from early terrestrial and lunar anorthosites. Early terrestrial anorthosites have lower whole-rock An contents but similar Mg# to lunar anorthosites. The CaO contents of lunar anorthosites are higher than those of early terrestrial anorthosites for a given MgO and Al2O3 content, early terrestrial anorthosites have higher SiO2 contents than lunar anorthosites at a given MgO content, and lunar anorthosites have higher Eu/Eu* anomaly ratios yet broadly similar La/Yb and Nd/Sm ratios than early terrestrial anorthosites. Some early terrestrial anorthosites have less fractionated chondrite-normalised rare earth element (REE) patterns and less prominent positive Eu anomalies than lunar anorthosites. Lunar anorthosites have higher plagioclase An contents, yet a similar range of pyroxene Mg# compared to their early terrestrial counterparts. Some early terrestrial anorthosites are more fractionated than some lunar anorthosites. Our interpretations imply that most early terrestrial anorthosites crystallised from basaltic parental magmas that were generated by high-degree partial melting of sub-arc asthenosphere mantle wedge sources that were hydrated by slab-derived fluids, with the remainder being associated with mid-ocean ridge and mantle plume settings. Some of the arc-related early terrestrial anorthosites were influenced by crustal contamination. In addition, early terrestrial anorthosites originated from partial melting of the mantle at various depths with variable garnet residua, whereas lunar anorthosites formed without any significant garnet residua. Lower plagioclase CaO contents and pyroxene Mg# in early terrestrial anorthosites can be explained by higher proportions of clinopyroxene and olivine fractionation in terrestrial magma chambers than in the lunar magma ocean where orthopyroxene and olivine fractionation occurred. Low TiO2 contents in both terrestrial and lunar anorthosites reflect rutile and/or ilmenite fractionation.
Geoscience frontiersEarth and Planetary Sciences-General Earth and Planetary Sciences
CiteScore
17.80
自引率
3.40%
发文量
147
审稿时长
35 days
期刊介绍:
Geoscience Frontiers (GSF) is the Journal of China University of Geosciences (Beijing) and Peking University. It publishes peer-reviewed research articles and reviews in interdisciplinary fields of Earth and Planetary Sciences. GSF covers various research areas including petrology and geochemistry, lithospheric architecture and mantle dynamics, global tectonics, economic geology and fuel exploration, geophysics, stratigraphy and paleontology, environmental and engineering geology, astrogeology, and the nexus of resources-energy-emissions-climate under Sustainable Development Goals. The journal aims to bridge innovative, provocative, and challenging concepts and models in these fields, providing insights on correlations and evolution.