{"title":"Diversification inside a lamprophyric dyke and cone sheet complex converging onto a hidden carbonatite centre (Frederikshåbs Isblink, SW Greenland)","authors":"Martin Bromann Klausen, Madelaine R Frazenburg","doi":"10.1017/s0016756824000165","DOIUrl":null,"url":null,"abstract":"<p>Both radiating dykes and proximal cone sheets converge onto a positive aeromagnetic anomaly of an inferred carbonatitic centre, hidden beneath a retreating edge of the Frederikshåbs Isblink glacier. This convergence, together with sub-parallel incompatible element patterns by all intrusions, suggests a cogenetic relationship that warrants investigation into potential diversification processes. More primitive high- and low-Mg damtjernites, which for three dykes conform to more porphyritic dyke cores and aphyric margins, respectively, can be explained by high-Mg trends being controlled by the fractionation/accumulation of mainly augite and olivine (or other mafic phases), while discordant low-Mg trends require additional decoupled magnetite fractionation. It is proposed that each dyke intrusion tapped the differentiated top of a central magma chamber, occasionally followed by an unconsolidated mafic cumulate mush, excluding denser magnetites, with <span>in situ</span> flow segregation playing a subordinate additional role. Beyond the most differentiated damtjernite, more evolved phonolitic nephelinites to carbonaceous alnöites split into bulk rock geochemical T-trends that can only relate to late-stage segregations into magmas with varying proportions of interstitial igneous (not secondary) analcime and carbonate – collectively increasing in volume with differentiation. While the analcime component also appears to segregate more readily into veins and ocelli than carbonatite, it is speculated if such low viscosity, density and liquidus rest melts, inside igneous centres, more efficiently aggregated into voluminous, buoyant analcime caps above slightly denser carbonatites. Similar converging plumbing systems and diversification processes are proposed for other complexes, where kimberlitic parents were simply extracted from deeper mantle sources.</p>","PeriodicalId":12612,"journal":{"name":"Geological Magazine","volume":null,"pages":null},"PeriodicalIF":2.0000,"publicationDate":"2024-09-19","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Geological Magazine","FirstCategoryId":"89","ListUrlMain":"https://doi.org/10.1017/s0016756824000165","RegionNum":3,"RegionCategory":"地球科学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q3","JCRName":"GEOSCIENCES, MULTIDISCIPLINARY","Score":null,"Total":0}
引用次数: 0
Abstract
Both radiating dykes and proximal cone sheets converge onto a positive aeromagnetic anomaly of an inferred carbonatitic centre, hidden beneath a retreating edge of the Frederikshåbs Isblink glacier. This convergence, together with sub-parallel incompatible element patterns by all intrusions, suggests a cogenetic relationship that warrants investigation into potential diversification processes. More primitive high- and low-Mg damtjernites, which for three dykes conform to more porphyritic dyke cores and aphyric margins, respectively, can be explained by high-Mg trends being controlled by the fractionation/accumulation of mainly augite and olivine (or other mafic phases), while discordant low-Mg trends require additional decoupled magnetite fractionation. It is proposed that each dyke intrusion tapped the differentiated top of a central magma chamber, occasionally followed by an unconsolidated mafic cumulate mush, excluding denser magnetites, with in situ flow segregation playing a subordinate additional role. Beyond the most differentiated damtjernite, more evolved phonolitic nephelinites to carbonaceous alnöites split into bulk rock geochemical T-trends that can only relate to late-stage segregations into magmas with varying proportions of interstitial igneous (not secondary) analcime and carbonate – collectively increasing in volume with differentiation. While the analcime component also appears to segregate more readily into veins and ocelli than carbonatite, it is speculated if such low viscosity, density and liquidus rest melts, inside igneous centres, more efficiently aggregated into voluminous, buoyant analcime caps above slightly denser carbonatites. Similar converging plumbing systems and diversification processes are proposed for other complexes, where kimberlitic parents were simply extracted from deeper mantle sources.
辐射堤和近端锥片都汇聚到一个推断为碳酸盐岩中心的正航空磁异常上,该中心隐藏在腓特烈克肖布-伊斯布林克冰川后退的边缘之下。这种趋同性,以及所有侵入体的次平行不相容元素模式,表明了一种同源关系,值得对潜在的多样化过程进行研究。更原始的高镁和低镁达姆特杰尼特岩(三个堤坝分别与更多斑岩堤核和斑岩边缘相吻合)可以解释为高镁趋势主要由辉石和橄榄石(或其他黑云母相)的分馏/累积所控制,而不和谐的低镁趋势则需要额外的解耦磁铁矿分馏。据推测,每条筑堤侵入体都是从一个中央岩浆室的分异顶端开始的,偶尔会出现未固结的黑云母积泥,其中不包括密度较大的磁铁矿,而原地流动偏析则起着从属的附加作用。在分化程度最高的达姆特杰尼特岩之外,从声母质霞石到碳质白云石的演化过程中,会出现大块岩石地球化学 T 型趋势,这只能与后期分离成岩浆的过程有关,岩浆中含有不同比例的间质火成岩(非次生)类石灰和碳酸盐--随着分化的进行,它们的体积会共同增大。与碳酸盐岩相比,岩浆中的芒硝成分似乎更容易分离成矿脉和鲕粒,因此可以推测,在火成岩中心内部,这种低粘度、低密度和低液休的熔体是否能更有效地聚集成体积大、浮力强的芒硝帽,并将其置于密度稍高的碳酸盐岩之上。还提出了其他岩群类似的聚合管道系统和多样化过程,在这些岩群中,金伯利岩母体只是从更深的地幔源中提取出来的。
期刊介绍:
Geological Magazine, established in 1864, is one of the oldest and best-known periodicals in earth sciences. It publishes original scientific papers covering the complete spectrum of geological topics, with high quality illustrations. Its worldwide circulation and high production values, combined with Rapid Communications and Book Review sections keep the journal at the forefront of the field.
This journal is included in the Cambridge Journals open access initiative, Cambridge Open Option.