斯卡尔加德层状系列岩石学

IF 2 4区 地球科学 Q1 GEOLOGY Geus Bulletin Pub Date : 2023-12-22 DOI:10.34194/geusb.v56.8327
P. Thy, C. Tegner, C. Lesher
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引用次数: 0

摘要

斯凯尔加德侵入体是早始新世期间在东格陵兰的断裂火山边缘隆起的铁质玄武岩侵入体。岩浆室在冷却过程中从顶部和边缘向上和向内结晶,形成上部、边缘和底部系列,后者被称为层状系列。底部系列的相分层表明,橄榄石-正长岩-透辉石熔体已经进化,斜长石和橄榄石达到饱和,随后是奥氏体,然后同时是钛铁矿和磁铁矿,形成了原始岩体。褐铁矿出现在下部,并一直持续到系列的中心。磷灰石出现在上部,同时伴有液不溶性。单个原岩的隐伏变化记录了铁质矿物中铁的系统性增加和镁的系统性减少,以及斜长石中钠的系统性增加和钙的系统性减少。鸽血石的出现是由于受困熔体中的反应和结晶以及未达到液相饱和的亚固结调整造成的。上部底部橄榄石的高模式与磷灰石的出现被解释为液态不溶性的开始。这可能导致了共轭熔体的分离,粒岩向上移动,而基本组分则基本保持静止或下沉。岩石学和地球化学观测结果表明,侵入体下部的分异主要由晶体分馏控制,分馏的效率则由凝固泥浆中液体的演化和逸出控制。在凝固的最后阶段,液体不溶性的出现和熔体对流的终止阻碍了分化。用完全瑞利分馏法建立的模型显示,主要元素和包含的微量元素与观测结果基本吻合,而排除的元素则偏离了模型预测。这种脱钩是由于在被困熔体和主要残余岩浆腔中形成的花岗岩成分的流动性造成的。因此,取样的辉长岩可能并不代表最终的固体熔融物。通过将辉长岩还原为原始的熔浆成分,就有可能限制粒岩的迁移路径。我们认为,在侵入体下部受困熔体中形成的花岗岩大多通过压力释放途径横向迁移,形成透镜状和袋状,只有有限的向上迁移到主岩浆库中。在接近分异末期,残余岩浆外溶,形成了铁质玄武岩熔体和花岗岩熔体的复杂混合物。据估计,大量花岗岩熔体以岩柱的形式渗入向下结晶的岩体上部以及母岩中。花岗岩熔体在凝固晶泥中的重新分布,使受困熔体含量的预测和质量平衡计算变得复杂,但有助于解释包含和排除微量元素的明显脱钩,特别是在演化的末期。最终结晶主要由原位结晶控制,留下了铁闪长岩和粒闪长岩成分的复杂混合物。
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Petrology of the Skaergaard Layered Series
The Skaergaard intrusion is a layered, ferrobasaltic intrusion emplaced during the Early Eocene into the rifting volcanic margin of East Greenland. The magma chamber crystallised in response to cooling from the roof and margins upwards and inward, forming upper, marginal and bottom series, the latter referred to as the Layered Series. The phase layering in the bottom series suggests an evolved, olivine-normative tholeiitic melt saturated in plagioclase and olivine, followed by augite, and then simultaneously by ilmenite and magnetite forming primocrysts. Pigeonite appears in the lower parts and continues until the centre of the series. Apatite appears in the upper part concurrently with liquid immiscibility. Cryptic variations of the individual primocrysts record a systematic upward increase in iron and decrease in magnesium for the mafic minerals and a systematic increase in sodium and decrease in calcium for plagioclase. The appearance of pigeonite is caused by reactions and crystallisation in the trapped melt and by subsolidus adjustments without this phase reaching liquidus saturation. The high mode of olivine at the base of the upper part with the appearance of apatite is interpreted to mark the onset of liquid immiscibility. This may have led to the separation of conjugate melts with granophyre migrating upward and the basic component largely staying stationary or sinking. Petrologic and geochemical observations indicate differentiation in the lower part of the intrusion, principally controlled by crystal fractionation with the efficiency of fractionation controlled by the evolution and escape of liquid from the solidifying mush. During the final stages of solidification, the onset of liquid immiscibility and termination of melt convection impeded differentiation. Modelling by perfect Rayleigh fractionation shows that major and included trace elements conform reasonably to observations, while excluded elements deviate from model predictions. This decoupling is caused by the mobility of a granophyre component formed in the trapped melt and in the main residual magma chamber. Consequently, the sampled gabbros may not be representative of the final solid-melt mush. By restoring the gabbros to their original mush compositions, it is possible to constrain granophyre migration pathways. We suggest that the granophyre formed in the trapped melt in the lower part of the intrusion mostly migrated laterally through pressure release pathways to form lenses and pockets with only limited upward migration into the main magma reservoir. Near the end stage of differentiation, the residual magma exsolved and formed complex mixtures of ferrobasaltic and granophyric melts. Estimates predict that a substantial amount of the granophyric melt penetrated as sills into the downward crystallising, upper part of the body as well as into the host rocks. The redistribution of granophyric melts within the solidifying crystal mush complicates predictions of trapped-melt content and mass-balance calculations but helps to explain apparent decoupling of included and excluded trace elements, especially towards the end stages of evolution. Final crystallisation was controlled mostly by in situ crystallisation leaving complex mixtures of ferrodiorite and granophyre components.
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来源期刊
Geus Bulletin
Geus Bulletin GEOLOGY-
CiteScore
2.80
自引率
17.60%
发文量
8
期刊最新文献
Petrology of the Skaergaard Layered Series Stratigraphy of the Upper Jurassic to lowermost Cretaceous in the Rødryggen-1 and Brorson Halvø-1 boreholes, Wollaston Forland, North-East Greenland  Organic geochemistry of an Upper Jurassic – Lower Cretaceous mudstone succession in a narrow graben setting, Wollaston Forland Basin, North-East Greenland Upper Jurassic – Lower Cretaceous of eastern Wollaston Forland, North-East Greenland: a distal marine record of an evolving rift Mudstone diagenesis and sandstone provenance in an Upper Jurassic – Lower Cretaceous evolving half-graben system, Wollaston Forland, North-East Greenland
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