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1.
安山岩是俯冲带岩浆弧中重要的岩石类型,其成因至今仍是国际地质学界研究的热点之一.根据安山岩分布的地质背景,岩浆弧安山岩可以简单划分为陆弧安山岩和洋弧安山岩,二者在化学成分和空间分布等方面存在明显差异.自20世纪20年代末以来,大量的研究成果丰富了人们对岩浆弧安山岩成因的认识,逐渐将其归纳为玄武质岩浆输入和安山质岩浆输入2种模型.玄武质岩浆输入模型认为形成岩浆弧安山岩的初始岩浆成分为玄武质,强调分离结晶、同化混染和岩浆混合等壳内过程;而安山质岩浆输入模型认为地幔源区可以直接形成安山质熔体,强调俯冲板片来源的流体/熔体—地幔橄榄岩的交代反应和沉积物底辟等壳下过程.虽然岩浆弧安山岩的成因研究取得了一定的进展,但每一个模型都有亟待完善之处.地幔交代岩的实验岩石学研究、安山岩与大陆地壳形成与演化间的关系、理论计算和模拟的应用等都是未来需要研究的领域. 相似文献
2.
对个旧锡矿的玄武岩和花岗岩进行了载锡能力的高温高压实验岩石学研究。结果表明:无论是花岗质还是玄武质岩浆,Sn4+都可以大量置换岩浆中的Si4+,形成富锡岩浆;个旧花岗质岩浆载锡最多可达约36%,而个旧玄武质岩浆载锡亦可达14.9%以上;当富锡的花岗质岩浆冷却时,岩浆将会出溶呈液滴状的锡的硫化物,表明花岗岩与锡矿有着直接的成因联系;而富锡玄武质岩浆由于快速淬火,且形成温度较高,不利于形成锡的矿物,但是所形成的玄武岩仍具备形成锡矿源层的条件。因此,锡矿的成矿地质体并不单一,花岗质与玄武质岩浆均可能成矿,关键在于岩浆在其形成或运移过程中,是否从源区或围岩之中获得大量的锡。 相似文献
3.
富钾贫钙岩浆的成因探讨——来自岩石失水熔融实验分析 总被引:1,自引:0,他引:1
钾质-超钾质岩浆按CaO与MgO的含量和CaO与Mg#值的关系可划分出贫钙和富钙两种不同类型的原生岩浆.针对贫钙钾质-超钾质岩浆的成因问题,作者系统分析了岩石脱水熔融和失水熔融两种体系中岩石的熔融过程和熔体性质,通过对熔体组成与贫钙钾质岩浆成分的对比分析,提出富钾贫钙岩浆的断裂减压脱水熔融机制. 相似文献
4.
本文主要讨论穹窿-火山型攀西裂谷的成因,岩浆深成作用与火山作用过程;穹窿构造的发生、发展的演化历史;岩浆分异趋势及双峰式岩浆演化系列及其成因。 攀西裂谷曾经历了岩石圈穹窿—陆壳穹窿一次火山穹窿三个发展演化阶段。碱性岩浆作用与地壳隆升、地幔去气、热流汇聚作用有着密切的成因联系,成穹作用最盛,岩浆碱度最高。随着陆壳破裂、开放、挥发分散逸,岩浆性质从强碱质—弱碱质—碱酸性转化。 穹窿构造的发展演化阶段有机地控制了岩浆源和二次岩浆房的深度和岩浆演化特点,随着穹窿构造的发展演化,岩浆活动由深成幔源→中浅成幔源加陆壳轻微混染→超浅成壳幔混合源逐渐演化,因而可以认为:穹窿-火山型裂谷发育的各个阶段,存在有低位→中位→高位的二次岩浆房。 攀西裂谷属不发育的夭折裂谷,以演化时间长为特点,有利于岩浆深源(二次岩浆房内)结晶分异、液体不混容性分离作用和陆壳的同化混染作用等得以彻底进行,最终形成“双峰式”岩浆组合。 相似文献
5.
近十年来对锆石研究已从早期的U-Pb放射性同位素定年和锆石同位素分析,发展到大量研究锆石的微量元素。锆石微量元素不仅可以作为锆石Ti温度计估算岩浆温度,也可以用来识别锆石及其母岩的岩石类型和成因,区分岩浆熔体或者流体控制的岩浆作用、变质作用、成矿作用等深部作用过程。文中在归纳总结岩浆锆石、变质锆石、热液锆石、碎屑锆石等不同类型锆石的微量元素成分基础上,以青藏高原碰撞后超钾质岩石中产出的锆石为例,系统介绍了超钾质岩石中各类锆石的结构、年龄和微量元素特征,并应用于解释超钾质岩石成因、岩浆源区成分、岩浆演化和上部地壳物质的混染、下地壳加厚和高原隆升之间的关系。 相似文献
6.
白银地区细碧-石英角斑岩系成因 总被引:1,自引:0,他引:1
白银地区的细碧—石英角斑岩系,形成于岛弧或弧后盆地的板块构造环境。该构造环境具有形成拉斑玄武质岩浆的条件和存在钠质源区。细碧—石英角斑岩系的钠交代,发生在岩浆房上部,岩浆上升过程和海底环境。因而,该区细碧—石英角斑岩系既具有类似原生岩浆的结构特点,亦有很明显的碱质交代作用特征。其成因应归属次生交代成因。 相似文献
7.
桂北—湘南中生代玄武质岩石及其深源包体的地球化学性质和岩石成因探讨 总被引:9,自引:0,他引:9
桂北-湘南中生代玄武质岩石中含有丰富的深源包体,它们分别为橄榄岩、变形的辉长岩和中酸性片麻岩三大类,本文在论述上述岩石地球化学性质的基础上,探讨了它们之间的成因关系;寄主的中生代玄武质岩石为地幔楣榄岩部分熔融的产物,与辉长岩和中酸性片麻岩并无成因联系,后者属偶然包体,值得注意的是,深源包体中的变形辉长岩与片麻岩之间为分离结晶的成因关系,它们均为元古宙壳、幔间底侵玄武质岩浆的演化产物,其中辉长岩为底侵岩浆的堆积相,而片麻岩则为底侵岩浆经历分离结晶的堆积作用之后所剩下的残余岩浆的变质产物。 相似文献
8.
青藏高原岩浆岩成因研究:成果与展望 总被引:9,自引:5,他引:4
青藏高原是国际地学界公认的大陆动力学研究的天然实验室。岩浆是地球各层圈之间物质和能量交换的重要载体。岩浆岩及其所携带的深源岩石包体被当作探究地球深部的“探针”和“窗口”,同时也是板块运动与大地构造事件的记录。主要讨论青藏高原岩浆岩成因(特别是岩浆成因)研究的成就与存在的问题。首先阐述了关于青藏高原岩浆岩成因研究的基本思路。然后重点回顾了青藏高原岩浆岩成因研究的成果,包括冈底斯同碰撞花岗岩类的成因、钾质—超钾质火山岩的成因、埃达克质火成岩的成因、强过铝质花岗岩的成因、印度洋/特提斯地幔地球化学域的成因、与地幔柱活动有关的岩浆岩的成因,以及对“地球深部岩石的直接标本”的研究。最后提出了对今后青藏高原岩浆岩成因研究的展望。 相似文献
9.
南秦岭东江口岩体闪长质包体地球化学特征及成因探讨 总被引:6,自引:0,他引:6
本文对南秦岭东江口岩体中的闪长质包体的主量元素,微量元素地球化学特征及包体形成的温度和压力条件进行分析,揭示出闪长质包体与寄主岩体是同源的混溶包体。根据新的成因解释,认为不混溶包体的形成机理是由均一岩浆在演化过程中长英质岩浆和铁镁质岩浆有序化的结果。在有序化过程中,其具体过程可能是复杂的 相似文献
10.
新疆西准噶尔地区克拉玛依花岗质岩体中发育大量闪长质微粒包体,并形成有岩浆混合成因的岩浆混合岩——石英闪长岩。包体成分主要为闪长质,显微镜下具有岩浆岩结构,岩浆混合特征十分明显,如:针状磷灰石,角闪石包裹辉石残晶,长石斑晶的溶蚀环带等特征。岩体中寄主岩石、岩浆混合岩、闪长质微粒包体、闪长玢岩脉分别代表岩浆混合演化过程中两端元岩浆按不同比例混合的产物。在岩石地球化学方面,包体与寄主岩石的主要氧化物之间具有良好的线性关系,寄主岩石和包体的稀土元素配分曲线和微量元素蛛网图形态相似;各种地球化学元素参数特征显示,寄主岩石与包体在岩石形成过程中发生过成分交换及均一化。特征元素比值及同位素等特征表明,闪长质包体的端元岩浆可能为幔源基性岩浆,寄主岩石的端元岩浆可能是以壳源为主的酸性岩浆。岩石地球化学特征进一步佐证了该区岩浆混合作用的存在,同时也暗示岩浆混合作用可能是新疆北部后碰撞过程中重要的岩浆活动形式。 相似文献
11.
V. I. Kovalenko V. V. Yarmolyuk V. P. Kovach D. V. Kovalenko A. M. Kozlovskii I. A. Andreeva A. B. Kotov E. B. Salnikova 《Petrology》2009,17(3):227-252
The paper reports data on the Nd isotopic composition and the evaluated composition of the sources of magmatism that produced massifs of alkali and basic rocks of the Khaldzan-Buregtei group. The massifs were emplaced in the terminal Devonian at 392–395 Ma in the Ozernaya zone of western Mongolia. The host rocks of the massifs are ophiolites of the early Caledonian Ozernaya zone, which were dated at 545–522 Ma. The massifs were emplaced in the following succession (listed in order from older to younger): (1) nordmarkites and dolerites syngenetic with them; (2) alkali granites and syngenetic dolerites; (3) dike ekerites; (4) dike pantellerites; (5) rare-metal granitoids; (6) alkali and intermediate basites and quartz syenites; and (7) miarolitic rare-metal alkali granites. Our data on the Nd isotopic composition [?Nd(T)] and conventionally used (canonical) ratios of incompatible elements (Nb/U, Zr/Nb, and La/Yb) in rocks from the alkaline massifs and their host ophiolites indicate that all of these rocks were derived mostly from mantle and mantle-crustal enriched sources like OIB, E-MORB, and IAB with a subordinate contribution of N-MORB (DM) and upper continental crustal material. The variations in the ?Nd(T) values in rocks of these massifs suggest multiple mixing of the sources or magmas derived from them when the massifs composing the Khaldzan-Buregtei group were produced. The OIB and E-MORB sources were mixed when the rocks with mantle signatures were formed. The occurrence of nordmarkites, alkali granites, and other rocks whose isotopic and geochemical signatures are intermediate between the values for mantle and crustal sources testifies to the mixing of mantle and crustal magmas. The crustal source itself, which consisted of rocks of the ophiolite complex, was obviously isotopically and geochemically heterogeneous, as also were the magmas derived from it. The model proposed for the genesis of alkali rocks of the Khaldzan-Buregtei massifs implies that the magmas were derived at two major depth levels: (1) mantle, at which the plume source mixed with an E-MORB source, and (2) crustal, at which the ophiolites were melted, and this gave rise to the parental magmas of the nordmarkites and alkali granites. The basites were derived immediately from the mantle. The mantle syenites, pantellerites, and rare-metal granitoids were produced either by the deep crystallization differentiation of basite magma or by the partial melting of the parental basites and the subsequent crystallization differentiation of the generated magmas. Differentiation likely took place in an intermediate chamber at depth levels close to the crustal (ophiolite) level of magma generation. Only such conditions could ensure the intense mixing of mantle and crustal magmas. The principal factor initiating magma generation in the region was the mantle plume that controlled within-plate magmatism in the Altai-Sayan area and the basite magmas related to this plume, which gave rise to small dikes and magmatic bodies in the group of intrusive massifs. 相似文献
12.
The Middle Miocene Tsushima granite pluton is composed of leucocratic granites, gray granites and numerous mafic microgranular enclaves (MME). The granites have a metaluminous to slightly peraluminous composition and belong to the calc‐alkaline series, as do many other coeval granites of southwestern Japan, all of which formed in relation to the opening of the Sea of Japan. The Tsushima granites are unique in that they occur in the back‐arc area of the innermost Inner Zone of Southwest Japan, contain numerous miarolitic cavities, and show shallow crystallization (2–6 km deep), based on hornblende geobarometry. The leucocratic granite has higher initial 87Sr/86Sr ratios (0.7065–0.7085) and lower εNd(t) (?7.70 to ?4.35) than the MME of basaltic–dacitic composition (0.7044–0.7061 and ?0.53 to ?5.24), whereas most gray granites have intermediate chemical and Sr–Nd isotopic compositions (0.7061–0.7072 and ?3.75 to ?6.17). Field, petrological, and geochemical data demonstrate that the Tsushima granites formed by the mingling and mixing of mafic and felsic magmas. The Sr–Nd–Pb isotope data strongly suggest that the mafic magma was derived from two mantle components with depleted mantle material and enriched mantle I (EMI) compositions, whereas the felsic magma formed by mixing of upper mantle magma of EMI composition with metabasic rocks in the overlying lower crust. Element data points deviating from the simple mixing line of the two magmas may indicate fractional crystallization of the felsic magma or chemical modification by hydrothermal fluid. The miarolitic cavities and enrichment of alkali elements in the MME suggest rapid cooling of the mingled magma accompanied by elemental transport by hydrothermal fluid. The inferred genesis of this magma–fluid system is as follows: (i) the mafic and felsic magmas were generated in the mantle and lower crust, respectively, by a large heat supply and pressure decrease under back‐arc conditions induced by mantle upwelling and crustal thinning; (ii) they mingled and crystallized rapidly at shallow depths in the upper crust without interaction during the ascent of the magmas from the middle to the upper crust, which (iii) led to fluid generation in the shallow crust. The upper mantle in southwest Japan thus has an EMI‐like composition, which plays an important role in the genesis of igneous rocks there. 相似文献
13.
《Gondwana Research》2013,24(4):1554-1566
The paradox of the Earth's continental crust is that although this reservoir is generally regarded as having differentiated from the mantle, it has an andesitic bulk composition that contrasts with the intrinsic basaltic composition of mantle-derived melts. Classical models for new crust generation from the mantle in two-stage processes fail to account for two fundamental facts: the absence of ultramafic residues in the lower crust and the hot temperature of batholith magma generation. Other models based on the arrival of already-fractionated silicic magmas to the crust have not received the necessary attention. Addition of new crust by relamination from below of subducted materials has been formulated as a process complementary to delamination of mafic residues. Here we show important support to relamination from below the lithosphere as an important mechanism for new crust generation in magmatic arcs of active continental margins and mature intraoceanic arcs. The new support is based on three independent lines: (1) thermo-mechanical modeling of subduction zones, (2) experimental phase relations and melt compositions of subducted materials and (3) geochemical relations between mafic granulites (lower crust) and batholiths (upper crust). The mineral assemblage and bulk geochemistry of lower crust rocks are compared with solid residues left after granite melt segregation. The implication is that an andesite magma precursor is responsible for the generation of new continental crust at active continental margins and mature oceanic arcs. According to our numerical and laboratory experiments, melting and eventual reaction with the mantle of subducted oceanic crust and sediments produce the andesite magmas. These ascend in the form of mantle wedge diapirs and are finally attached (relaminated) to the continental crust, where they crystallize partially and produce the separation of the solid fraction to form mafic granulites (lower crust) and granitic (sl) liquids to form the batholiths (upper crust). 相似文献
14.
A petrological and geochemical study on time-series samples from Klyuchevskoy volcano,Kamchatka arc 总被引:1,自引:0,他引:1
To understand the generation and evolution of mafic magmas from Klyuchevskoy volcano in the Kamchatka arc, which is one of the most active arc volcanoes on Earth, a petrological and geochemical study was carried out on time-series samples from the volcano. The eruptive products show significant variations in their whole-rock compositions (52.0–55.5 wt.% SiO2), and they have been divided into high-Mg basalts and high-Al andesites. In the high-Mg basalts, lower-K and higher-K primitive samples (>9 wt.% MgO) are present, and their petrological features indicate that they may represent primary or near-primary magmas. Slab-derived fluids that induced generation of the lower-K basaltic magmas were less enriched in melt component than those associated with the higher-K basaltic magmas, and the fluids are likely to have been released from the subducting slab at shallower levels for the lower-K basaltic magmas than for higher-K basaltic magmas. Analyses using multicomponent thermodynamics indicates that the lower-K primary magma was generated by ~13% melting of a source mantle with ~0.7 wt.% H2O at 1245–1260?°C and ~1.9 GPa. During most of the evolution of the volcano, the lower-K basaltic magmas were dominant; the higher-K primitive magma first appeared in AD 1932. In AD 1937–1938, both the lower-K and higher-K primitive magmas erupted, which implies that the two types of primary magmas were present simultaneously and independently beneath the volcano. The higher-K basaltic magmas evolved progressively into high-Al andesite magmas in a magma chamber in the middle crust from AD 1932 to ~AD 1960. Since then, relatively primitive magma has been injected continuously into the magma chamber, which has resulted in the systematic increase of the MgO contents of erupted materials with ages from ~AD 1960 to present. 相似文献
15.
Continental flood basalts (CFBs), thought to preserve the magmatic record of an impinging mantle plume head, offer spatial and temporal insights into melt generation processes in large igneous provinces (LIPs). Despite the utility of CFBs in probing mantle plume composition, these basalts typically erupt fractionated compositions, suggestive of significant residence time in the continental lithosphere. The location and duration of residence within the lithosphere provide additional insights into the flux of plume-related magmas. The NW Ethiopian plateau offers a well-preserved stratigraphic sequence from flood basalt initiation to termination, and is thus an important target for study of CFBs. This study examines modal observations within a stratigraphic framework and places these observations within the context of the magmatic evolution of the Ethiopian CFB province. Data demonstrate multiple pulses of magma recharge punctuated by brief shut-down events, with initial flows fed by magmas that experienced deeper fractionation (lower crust). Broad changes in modal mineralogy and flow cyclicity are consistent with fluctuating changes in magmatic flux through a complex plumbing system, indicating pulsed magma flux and an overall shallowing of the magmatic plumbing system over time. The composition of plagioclase megacrysts suggests a constant replenishing of new primitive magma recharging the shallow plumbing system during the main phase of volcanism, reaching an apex prior to flood basalt termination. The petrostratigraphic data sets presented in this paper provide new insight into the evolution of a magma plumbing system in a CFB province. 相似文献
16.
地幔柱成矿系统:以峨眉山地幔柱为例 总被引:40,自引:3,他引:37
地幔柱沟通了地核、地幔、地壳各个圈层之间的物质与能量交换,提供了板内构造岩浆活动及成矿作用的一种重要的动力学机制。峨眉山地幔柱是晚古生代全球最显著的地幔柱活动之一,形成了多种有重大资源经济价值的矿床类型。以峨眉山地幔柱为例,对几种典型矿床类型的产出特征及成因进行了系统分析,阐述了地幔柱成矿系统中各种成矿作用与地幔柱构造岩浆活动的关系及成矿机理。(1)通过对部分典型岩浆硫化物矿床的地质地球化学特征和矿化特征分析,揭示了峨眉山大火成岩省不同矿化特征的岩浆硫化物矿床形成于统一的地幔柱岩浆活动体系,并与峨眉山玄武岩为同源演化关系,岩浆演化过程及硫化物熔离富集过程存在的差异造成了矿化类型的变异。(2)对攀西地区4个超大型钒钛磁铁矿矿床进行了详尽的地质地球化学分析,论述了成矿岩浆的性质、与峨眉山玄武岩的关系及成岩演化过程和成矿模式,表明成矿母岩浆来自于地幔柱,但经历了较大程度的地壳混染作用,提出岩浆的多次补给混合及结晶锋面上发生的双扩散造成的液态分层导致了韵律条带矿石的形成。(3)阐述了滇黔相邻地区玄武岩型自然铜和黑铜矿铜矿化现象,指出玄武岩岩浆气液阶段的自变质作用和玄武岩构造变质热液蚀变改造作用两种方式造成铜矿化富集,岩浆气液阶段的自变质作 相似文献
17.
N. S. Gorbachev 《Petrology》2010,18(4):416-431
The paper reports data on the geology and tectono-magmatic reactivation of the Norilsk area and on the stratigraphy and geochemistry
of its volcanic sequence, with the discussion of the sources and genesis of the ore magmas and the scale of the ore-forming
process. According to the geochemistry of the lavas and intrusive rocks (Ti concentration and the La/Sm and Gd/Yb ratios),
two types of the parental magmas are recognized: high-Ti magmas of the OIB type (from bottom to top, suites iv, sv, and gd
of phase 1) and low-Ti magmas (suites hk, tk, and nd of phase 2 and suites mr-mk of phase 3), which were derived from the
lithospheric mantle. The magmatic differentiation of the parental low-Ti magma of the tk type into a magma of the nd type
was associated with the derivation of an evolved magma of the nd type, which was depleted in ore elements, and an ore magma,
which was a mixture of silicate and sulfide melts, protocrysts of silicate minerals, and chromite. Judging from their geochemical
parameters, the intrusions of the lower Norilsk type were comagmatic with the lavas of the upper part of the nd suite, and
the ore-bearing intrusions of the upper Norilsk type were comagmatic with the lavas of the mr-mk suites. When the ore-bearing
intrusions were emplaced, their magmas entrained droplets of sulfide melt and protocrysts of olivine and chromite and brought
them to the modern magmatic chamber. These protocrysts are xenogenic with respect to the magma that formed the intrusions.
In certain instances (Talnakh and Kharaelakh intrusions), the moving magma entrained single portions of sulfide magma, which
were emplaced as individual subphases. The experimental study of the peridotite-basalt-fluid system shows that mantle reservoirs
with protoliths of subducted oceanic crustal material could serve as sources of relatively low-temperature (1250–1350°C) high-Ti
magnesian magmas of the rifting stage from an olivine-free source. 相似文献
18.
碳酸岩与铂族元素地球化学 总被引:1,自引:1,他引:0
碳酸岩(carbonatite)被视为一种研究大陆地幔地球化学的“探针岩石”,通过对这类岩石的研究,在探讨地幔组成与演化、地幔交代作用与不均一性以及岩浆形成的动力学背景、岩浆来源及演化和有关矿产的成矿作用等方面,具有重要的理论意义和实际价值。铂族元素(Platinum—group elements,简称PGE)在研究核-幔分异、地幔组成与演化以及幔源岩石(主要为基性-超基性岩)形成的大地构造背景、岩浆起源及演化,以及探讨K/T界线与陨石撞击事件等方面具有重要意义。本文在概述国内外碳酸岩和PGE地球化学研究现状的基础上,结合地质事实和地球化学研究成果,认为碳酸岩熔体具有一定携带PGE的能力,可利用PGE地球化学来探讨碳酸岩的源区特征和岩浆形成与演化过程;同时指出,碳酸岩PGE地球化学研究过程中还存在许多悬而未决的科学问题。 相似文献
19.
The Trinity ophiolite consists of small magma chambers inside a large mantle body. Xenoliths of mantle peridotite occur both in gabbroic cumulates along the walls and in the matrices of ultrabasic breccias on the floors of the magma chambers. Field relationships and petrographic data suggest that these fragments of original mantle peridotite were modified by contact with basic magmas by modal metasomatism. Quantitative elemental mass transfers determined from the composition, volume and density variations of reacting minerals demonstrate both closed and open system conditions for the major (Si, Al, Ti, Na, Ca, Fe and Mg) and trace elements (Cr, Ni). In the open system, material gains and losses provide information on the composition of the fluid taking part in the metasomatic reaction.
During a first stage of metasomatism the mantle xenoliths were affected by high-temperature reactions at 600 to 925°C. They resulted from the interaction between solid mantle lherzolites and basic melts. The reactions are:
1. (1)those forming orthopyroxene-magnetite simplectite
2. (2)those forming plagioclase-magnetite corona
3. (3)clinopyroxene+spinel I→pargasitic hornblende+spinel II.
Chemical interactions between the upper mantle and oceanic magma chambers occurred as soon as the basic magmas had ascended through the upper mantle. The chemically modified magmas, within oceanic magma chambers, were depleted in Ti, Fe and Na. This could partly explain regional variations of the chemical compositions of primary magmas produced beneath slow-spreading ridges. The breakdown of olivine to orthopyroxene and magnetite participates in the control of the partition of magnetic Fe---Ti oxides between oceanic crust and mantle.
During the second stage, the serpentinization of olivine and the production of talc were superimposed on the products of the first stage. These reactions require large amounts of H2O. The hydrothermal fluid was probably seawater. It circulated in the brecciated area along the walls and floors of the magma chambers located at shallow depths. Such structural discontinuities thus played the role of penetration channels favoring seawater circulation in the oceanic crust.
All the chemical reactions examined suggest a significant open-system element transfer by infiltrating melts or circulating fluids. The results of this study suggest that caution is required in the interpretation of mineralogical and chemical information provided by mantle xenoliths carried to the surface by ascending magmas. 相似文献
20.
Nickel content of basaltic magmas: identification of primary magmas and a measure of the degree of olivine fractionation 总被引:4,自引:0,他引:4
Hiroaki Sato 《Lithos》1977,10(2):113-120
Available NiO analyses of olivine in peridotites of probable mantle origin are consistent in giving values around 0.40 weight per cent. Assuming that basaltic magma forming from the mantle was in equilibrium with such peridotitic olivine, the NiO content of primary basaltic magmas is estimated to be about 0.030–0.050 weight per cent. The fractionation behaviour of nickel in basaltic magma due to the crystallization of olivine has been calculated using constant NiMg and FeMg exchange partition coefficients between olivine and magma. It is shown that the NiO content of both magma and olivine decreases by 50 per cent after fractional crystallization of 6–12 per cent of olivine. The nickel distribution in some basaltic rocks and olivines is examined in the light of these results, and it is suggested that basaltic magmas, such as some of the ocean-floor basalt and the Hawaiian tholeiite and alkali basalts, represent primary magmas from mantle peridotites. 相似文献