{"title":"大洋和大陆地幔构造中的Re-Pt-Os同位素和高亲铁元素行为","authors":"Tectonites, H. Becker, C. Dale","doi":"10.2138/RMG.2016.81.7","DOIUrl":null,"url":null,"abstract":"Tectonically emplaced mantle rocks, such as ophiolites, abyssal peridotites, and orogenic peridotite massifs, provide a principle constraint on the composition of and processes in the Earth’s upper mantle (Bodinier and Godard 2003). In the past, these ‘mantle tectonites’ have sometimes received different names because their history and origin has been unclear. Mantle tectonites are now understood to reflect a range of geologic environments regarding their emplacement and their origin (e.g., Dilek and Furnes 2014). The advantage of these rocks compared to mantle xenoliths is the large-scale exposure of textural and compositional relations between different rock types that can be used to identify processes such as melting, magma or fluid transport, chemical reactions, mixing or deformation at a range of spatial scales. 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引用次数: 54
摘要
构造侵位的地幔岩石,如蛇绿岩、深海橄榄岩和造山橄榄岩块,对地球上地幔的组成和过程提供了一个原则性的约束(Bodinier和Godard 2003)。在过去,这些“地幔构造岩”有时会有不同的名字,因为它们的历史和起源一直不清楚。地幔构造岩现在被理解为反映了一系列关于其就位和起源的地质环境(例如,Dilek和Furnes 2014)。与地幔捕虏体相比,这些岩石的优势在于可以大规模地揭示不同岩石类型之间的结构和成分关系,这些关系可用于识别熔融、岩浆或流体运输、化学反应、混合或在一定空间尺度上的变形等过程。大多数地幔构造岩的一个缺点是,它们通常表现出一些元素的实质性化学修饰,这是由于在低温下广泛的蛇纹石化造成的。在某些情况下,这也可能影响一些高度亲铁元素的丰度(HSE: Re, Au, PGE: Os, Ir, Ru, Rh, Pt, Pd),然而,这可以通过与相似组成的未蚀变岩石进行比较来测试。正如Luguet和Reisberg(2016,本卷)、Harvey等人(2016,本卷)和Aulbach等人(2016,本卷)所讨论的那样,橄榄岩捕虏体在硫化物和亲铜元素方面有自己的蚀变问题。许多研究已经在许多不同类型的地幔构造岩上获得了Os同位素和/或高亲铁元素丰度数据。其中一些研究集中在大尺度的化学和同位素变化上,另一些研究集中在粒度尺度的成分变化上,以了解小尺度的分布过程。这些研究共同极大地推进了对地幔中HSE在不同空间尺度上的分馏过程的理解,并为地幔中硫化物的行为提供了见解。
Re–Pt–Os Isotopic and Highly Siderophile Element Behavior in Oceanic and Continental Mantle Tectonites
Tectonically emplaced mantle rocks, such as ophiolites, abyssal peridotites, and orogenic peridotite massifs, provide a principle constraint on the composition of and processes in the Earth’s upper mantle (Bodinier and Godard 2003). In the past, these ‘mantle tectonites’ have sometimes received different names because their history and origin has been unclear. Mantle tectonites are now understood to reflect a range of geologic environments regarding their emplacement and their origin (e.g., Dilek and Furnes 2014). The advantage of these rocks compared to mantle xenoliths is the large-scale exposure of textural and compositional relations between different rock types that can be used to identify processes such as melting, magma or fluid transport, chemical reactions, mixing or deformation at a range of spatial scales. A disadvantage of most mantle tectonites is that they commonly display substantial chemical modification of some elements, resulting from widespread serpentinization at low temperatures. In some cases, this may also affect abundances of several of the highly siderophile elements (HSE: Re, Au, PGE: Os, Ir, Ru, Rh, Pt, Pd), however, this can be tested by comparison with unaltered rocks of similar composition. As is discussed in Luguet and Reisberg (2016, this volume), Harvey et al. (2016, this volume) and Aulbach et al. (2016, this volume), peridotite xenoliths have their own alteration issues regarding sulfides and chalcophile elements. Numerous studies have obtained Os isotope and/or highly siderophile element abundance data on many different types of mantle tectonites. Some of these studies have focused on large-scale chemical and isotopic variations, others on grain size-scale compositional variations to understand small-scale distribution processes. These studies have, together, significantly advanced the understanding of the processes that fractionate the HSE in the mantle at different spatial scales and have provided insights into the behavior of sulfide in the mantle—the phase that typically …
期刊介绍:
RiMG is a series of multi-authored, soft-bound volumes containing concise reviews of the literature and advances in theoretical and/or applied mineralogy, crystallography, petrology, and geochemistry. The content of each volume consists of fully developed text which can be used for self-study, research, or as a text-book for graduate-level courses. RiMG volumes are typically produced in conjunction with a short course but can also be published without a short course. The series is jointly published by the Mineralogical Society of America (MSA) and the Geochemical Society.
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