地幔平衡部分熔融和岩浆分离结晶成因岩浆岩的判别

本文在讨论Ⅰ型（地幔平衡部分熔融成因）和Ⅱ型（岩浆分离结晶成因）岩浆岩元素丰度关系公式的基础上，建立了Ⅰ型和Ⅱ型岩浆岩系成因判别公式及判别法则。     

地幔平衡部分熔融和岩浆分离结晶成因岩浆岩的差别

本文对讨论了１型（地幔平衡部分熔融成因）和Ⅱ型（岩浆分离结晶成因）岩浆岩元素丰度关系公式的基础上，建立了Ⅰ型和Ⅱ型岩系成因差别公式及差别法则。     

闽西基性脉岩成岩方式的判别

地幔平衡部分熔融过程中，微量元素在原始岩浆中(熔体)和初始固相母体物质中(地幔)遵循以下关系：C^iL／C^oL=1／[D F(1-D)]；分离结晶成因的岩浆岩系，微量元素在残余岩浆中(C^iL)和母岩浆中(C^oL)遵循如下关系式：C^iL=C^iL*F^D-1。微量元素在部分熔融和分离结晶成岩方式中有独立的分布规律，因此利用微量元素对或比值的图解就可判别岩体(或脉岩)的成岩方式。选取微量元素Th-Yb、La-La／Yb、Th-Cr和Th-Ni图解对闽西基性脉岩成岩方式进行判别，发现闽西三个地区的基性脉岩均为地幔部分熔融作用所致，从而印证了闽西基性脉岩不是酸性岩浆演化的产物。     

峨眉山玄武岩地幔源成分及其变化的微量元素标志

根据峨眉山玄武岩系岩石的稀土元素、不相容元素特征，估计了产生其母岩浆的地幔源成分。讨论了地幔平衡部分熔融和岩浆分离结晶过程中强不相容元素与一般不相容元素的比值变化后，提出用双对数图解来判别地幔成分、元素总分配系数及母岩浆形成时地幔熔融度的原理。根据Ｌａ，Ｃｅ和Ｓｃ，Ｙｂ在地幔－岩浆过程中地球化学特征，运用上述原理，讨论了峨眉山玄武岩系母岩浆的地幔成分及其变化，计算了地幔矿物相组成和部分熔融度。     

堆积岩与岩浆岩成分趋势线的相互预测原理及方法

本文在讨论了同源岩浆分离结晶过程中堆积相与残余岩浆相元素丰度关系公式的基础上，提出了堆积岩与相对应的（同源同结晶阶段）岩浆岩（狭义）成分趋势线的相互预测法则，并以冰岛玄武岩－流纹岩系和攀西地区峨眉山玄武岩系及相对应的层状堆积岩为例，厘定了多期岩浆分离结晶成因堆积岩系与岩浆岩系成分趋势相互预测的作图方法。     

岩浆分离结晶成因岩浆岩微量元素丰度公式的讨论

本文讨论了微量元素丰度研究在国內外的现状、存在问题及解决途径。在攀西地区米易白马层状基性、超基性岩体及相邻玄武岩系研究的基础上,提出了对于岩浆分离结晶成因岩浆岩微量元素丰度所遵守的通式,即分离结晶成因岩浆岩微量元素丰度互呈幂函数关系。并讨论了两种元素含量关系的几种基本形式。人们能够以此定性和定量地探索一系列有关岩石成因的具体问题。     

一种改进的简单的估算原始岩浆的方法

利用橄榄石和熔浆的Fe—Mg分配系数,制作了MgO—FeO演化图解。根据MgO—FeO体系中Fo橄榄石的Fo值:Fo=n(Mg)÷n(Mg)+n(Fen(Mg)/n(Mg)+n(Fe))等值线与Fe—Mg演化曲线交点确定原始岩浆成分。该图解优点在于可以更简单、直观地判别原始岩浆成分,适用于橄榄石分离结晶体系。同时介绍了该图解的使用方法,并以峨眉山大火成岩省丽江地区的大具与仕满两个剖面的苦橄岩为例,说明如何应用该图解来恢复原始岩浆以及解释岩石的成因。研究结果表明,仕满地区原始岩浆MgO、FeO含量分别为23.5%和12.8%,部分熔融程度较高,SM-14和SM-15是由仕满原始岩浆经过轻度橄榄石分离结晶形成的,基本可以代表原始岩浆成分。大具地区原始岩浆可分为两类,一类部分熔融程度较低,MgO、FeO含量分别为19.8%和11.3%;另一类部分熔融程度较高,MgO、FeO含量分别为23%和13.3%,与仕满原始岩浆成分类似。大具地区的岩石样品成分均不能代表该地区的原始岩浆成分,而是经历了明显的橄榄石分离结晶作用。另外,峨眉山大火成岩省中绝大多数的玄武岩中CaO含量不符合橄榄石分离结晶关系,并且MgO含量一般都低于8%,以及岩石中普遍出现单斜辉石和斜长石矿物等都表明这些玄武岩不可能由地幔部分熔融形成的原始岩浆直接通过橄榄石分离结晶作用形成。     

内蒙古阿巴嘎旗地区新生代玄武岩基本特征及成因

内蒙古阿巴嘎旗及其以北地区新生代玄武岩是更新世中心式火山活动产生的大陆溢流玄武岩,该区玄武岩以高碱、富钛、贫铝为特征,属于钠质碱性玄武岩系列.源区是软流圈上地幔,玄武岩是部分熔融和分离结晶两种作用的结果.地幔橄榄岩部分熔融产生玄武质岩浆,部分原始地幔岩浆未经变异沿构造通道直接喷出地表形成碧玄岩、碱性橄榄玄武岩;部分原始地幔岩浆在上升过程中因停顿,原始地幔岩浆发生橄榄石分离结晶作用,部分橄榄石从岩浆中析出,最终岩浆喷出地表形成橄榄拉斑玄武岩.研究该区新生代玄武岩基本特征,探讨岩浆起源和岩石产生的构造环境对认识该区岩石圈地幔和软流圈性质具有重要意义.     

分离结晶岩浆岩元素丰度关系定律的事实基础

根据中国西南峨眉山玄武岩一粗面岩系和同源的白马基性超基性岩体的地球化学研究发现:(1)对于分离结晶成因的岩浆岩,元素丰度互呈幂函数关系。报导了这一定律的事实依据,引证了安底斯山脉玄武岩—流纹岩系元素含量数据的系统证实实例。(2)指出:对同源同结晶阶段岩浆岩,元素含量关系有7种基本型式并遵守同一关系式。同源同结晶阶段岩浆岩元素丰度关系式是讨论同源不同结晶阶段岩浆岩元素丰度关系的基础。     

多期岩浆分离结晶作用中微量元素丰度关系

本文提出了多期岩浆分离结晶中元素丰度关系的数学表达式;阐述了微量元素正向演化和反向演化的机理;指出了在不同岩浆分离阶段一些微量元素丰度关系常数(R)有明显变化,可以此作为阶段划分的依据。由峨嵋山玄武岩系及基性-超基性层状岩体研究所得出的元素丰度关系式,适用于其他成分岩浆分离结晶成因的岩浆岩系。本文着重列举数据较齐全的智利安底斯山脉玄武岩、玄武安山岩、安山岩、英安岩和流纹岩岩系的资料作为系统验证。     

Estimation of the Primary Magma Compositions of an Igneous Rock Series Petrogenetically Associated with Fractional Crystallization with Special Reference to Element Abundance Relationships

A primary magma not only represents the starting point of a fractional crystallization process, but also is the product of an equilibrium or fractional partial melting process in a mantle.Element abundance relationships in the primary magma obey both law of power function for fractional crystallization and the law of fractional linear function for equilibrium partial melting .Based on this double nature of the primary magma, the authors advanced a principle to restore the primary magma composition from that of an igneous rock series with petrogenesis of fractional crystallization and put forward an approach of estimating the element abundance of the primary magma, exempli-fied by the rar-earth elements in the Andes volcanic rock series.     

滇西墨江西部石炭、二叠纪火山岩

墨江西部出露有石炭纪和晚二叠世两套火山岩,它们呈平行的两条带分布。石炭纪火山岩以拉斑玄武岩为主,少量流纹岩,它们是由上地幔源区10%部分熔融形成的原始岩浆,经橄榄石、辉石和斜长石不同程度结晶分异作用形成。其喷发环境可能是一个发育在大陆边缘的张性海盆地。晚二叠世火山岩较为复杂,熔岩与火山碎屑岩交互发育,熔岩主要属于拉斑系列,还含有少量钙碱性系列岩石;形成于陆缘火山弧环境。     

Deep differentiation of alkali ultramafic magmas: Formation of carbonatite melts

The study of melt microinclusions in olivine megacrysts from meimechites and alkali picrites of the Maimecha–Kotui alkali ultramafic and carbonatite province (Polar Siberia) revealed that the melt compositions corrected for loss of olivine due to post-entrapment crystallization of olivine on inclusion walls (differentiates of primary meimechite magma) match well to the composition of nephelinites and olivine melilitites belonging to carbonatite magmatic series. Modeling of fractional crystallization of meimechite magmas results in the high-alkali melt compositions corresponding to the silicate–carbonate liquid immiscibility field. The appearance of volatile-rich melts at the base of magma-generating plume systems at early stages of partial melting can be explained by extraction of incompatible elements including volatiles, by near-solidus melts at low degrees of partial melting, and meimechites are an example of such magmas. Subsequent accumulation of CO₂ in the residual melt results in generation of carbonate magma.     

Geochemistry and Petrogenesis of Three Series of Cenozoic Basalts from Southeastern China

Cenozoic basaltic volcanism in southeastern China was related to the lithospheric extension and asthenospheric upwelling at the eastern Eurasian continental margin. The cenozoic basaltic rocks from this region can be grouped into three different series: tholeiitic basalts, alkali basalts, and picritic-nephelinitic basalts. Each basalt series has distinctive geochemical features and is not derived from a common source rock by different degrees of partial melting or from a common parental magma by fractional crystallization. The mineralogy, petrography, and major and trace-element geochemistry of the tholeiites are similar to oceanic island basalts, implying that the mantle source for these Chinese continental tholeiites was similar to that of the oceanic island basalts—an asthenospheric mantle. The alkali basalts and picritic-nephelinitic basalts are enriched in incompatible trace elements, and their geochemical features can be interpreted as a result of partial melting of an enriched lithospheric mantle, or the mixing products of an asthenospheric magma with a component derived from an enriched lithospheric mantle through thermal erosion at the base of the lithosphere. But the lack of a transitional rock type and continuous variational trends among these basalts suggests that the mixing between asthenospheric magmas and lithospheric magmas probably was not significant in the petrogenesis of the basalts from SE China. Low-degree partial melting of enriched lithospheric mantle alone can account for the observed geochemical data from these basalts.     

河北汉诺坝碱性玄武岩的源区和成因

我国华北北部新近纪喷发的汉诺坝玄武岩,岩层出露比较完整,普遍含有超镁铁岩包体和各种高压巨晶。大麻坪代黄沟剖面出露较好,主要岩性为玄武岩,从上到下可分为上三、二、一层和底层。岩相学观察显示这些玄武岩含有1%~5%的捕虏晶且斑晶数量很少。橄榄岩包体为尖晶石二辉橄榄岩,轻稀土略微亏损,轻重稀土无分馏,显示这是只经过少量部分熔融后的原始地幔包体。通过对代黄沟碱性玄武岩中橄榄石、辉石和斜长石等斑晶或捕虏晶的矿物学分析,得出它们的成分变化是玄武岩混合了分解的地幔橄榄岩快速上升造成的。玄武岩的主量元素与二辉橄榄岩相平衡的原生熔体相比,Mg#(52.0~62.7)以及CaO(7.3%~8.5%)、Ni((82~192)×10-6)和Cr((65~192)×10-6)含量都较低。玄武岩的稀土分配模式为轻稀土富集的右倾型,δEu=1.01~1.05,δCe=0.95~1.02,富集高场强元素Nb、Ta、Zr及大离子亲石元素Ba、Sr。玄武岩痕量元素Ba/Rb和Rb/Sr的比值显示源区可能遭受过流体的交代作用。同时,痕量元素显示这一系列玄武岩主要受到部分熔融的控制,大量的结晶分异并未发生,且源区残留石榴子石。分析认为玄武岩岩浆应该是原生岩浆,而不是演化岩浆,影响整个岩浆的形成的过程可能是部分熔融而不是分离结晶。基于目前已发表的实验岩石学结果和理论分析认为汉诺坝玄武岩与辉石岩类相平衡,源区主要矿物相为单斜辉石和石榴子石,可能存在少量的橄榄石。     

“广西型花岗岩”有岩石学意义吗?——对《广西型花岗岩的地球化学特征及其构造意义》一文的质疑

对国内外30个实例的汇总表明,所谓"广西型花岗岩"不具备张旗(2014)所认为的岩石学和地球动力学意义。富Sr和Yb的"广西型花岗岩"在岩性包含了中性岩、酸性岩和过碱性岩,绝大多数具有负Eu异常。从岩石组合(系列)方面看,"广西型花岗岩"是钙碱性系列、碱性系列与A型花岗岩的"混杂"。"广西型花岗岩"可以是基性岩浆分离结晶或分离结晶+混染(AFC)、壳源岩石部分熔融等多种成岩机制的产物,斜长石是结晶相或残留相。对不同源岩的失水熔融相图的比较分析表明,花岗岩类的全岩Sr、Yb含量不是指示花岗质岩浆起源压力的可靠指标,张旗提出的以"Sr-Yb"为基础的花岗岩分类没有地球动力学意义。     

黑龙江五星铜镍、铂钯矿床镁铁质杂岩的元素地球化学特征与岩石成因

五星超镁铁质- 镁铁质杂岩的元素地球化学特征研究表明, 其原始岩浆为低钛、高镁的拉斑玄武岩浆, 由以CO2 为主的流体交代亏损地幔所形成的弱亏损地幔部分熔融产生, 其残余矿物相主要为石榴石、尖晶石和金红石。岩浆形成与演化经历了3 个阶段: ① 上升的软流圈与岩石圈地幔接触, 热流体作用导致岩石圈地幔发生高度部分熔融, 形成初始硫饱和的次碱性玄武岩; ②初始岩浆上侵, 在下地壳形成岩浆房, 岩浆结晶作用形成以似层状橄榄石、紫苏辉石、普通辉石和磁铁矿等为主的堆晶岩, 在地壳物质的参与下形成残余辉长质岩浆; ③ 岩浆房破裂, 残余岩浆和含有熔体( < 30% ) 的堆晶岩相先后上侵形成五星原始镁铁质杂岩。就铜镍和铂钯矿化而言, 铜镍硫化物形成于岩浆房分离结晶晚期的熔离作用, 而铂钯矿化则主要在成岩期后流体作用阶段形成。     

埃达克岩成因研究进展概述

埃达克岩提出之初是指那些源于俯冲带环境下,玄武质洋壳部分熔融形成的火山岩或者侵入岩.随后的研究发现,埃达克岩不仅仅只形成于岛弧环境,而具有多种成因模型：俯冲洋壳熔融、增厚下地壳熔融、拆沉下地壳熔融、玄武质岩浆的地壳混染和低压分离结晶（AFC）、高压分离结晶、岩浆混合作用以及地幔橄榄岩的直接熔融都可以形成与埃达克岩地球化学特征相同的岩石.这些研究成果丰富了我们对岛弧及下地壳岩浆活动的认识.     

Lead contents of S-type granites and their petrogenetic significance

An evaluation of Pb and Ba contents in S-type granites can provide important information on the processes of crustal partial melting. Primary low-T S-type granites, which form mainly by fluid-absent muscovite melting, may acquire a significant enrichment in Pb when compared to higher-T S-type granites for a given Ba content. We consider the following factors are responsible for this enrichment: Muscovite is a major carrier of Pb in amphibolite facies metapelites, and thus large quantities of Pb can be liberated upon its breakdown. The typical restite assemblage of Qz?+?Bt?+?Sil?±?Pl?±?Grt?±?Kfsp that forms during low-T, fluid-absent muscovite melting can take up only minor amounts of this Pb. This is because the crystal/melt Pb distribution coefficients for these restite minerals are low to very low. Only K-feldspar is moderately compatible for Pb, with a crystal/melt distribution coefficient of ~3, but its modal content in restites is usually low. At the same time, the restite assemblage will retain much Ba owing to the very high Ba uptake in both biotite and K-feldspar, which is an order of magnitude higher than for Pb. Thus, during a low-T anatectic event involving a low degree of crustal melting, Pb (as an incompatible element) can become strongly enriched in the partial melt relative to Ba and also relative to source rock values. In the case of higher-T anatexis and larger partial melt amounts, the Pb becomes less enriched and the Ba less depleted or even enriched relative to source rock values. During fractional crystallization of a S-type granite magma, Ba behaves strongly compatibly and Pb weakly compatibly. The concentrations of both elements decrease along the liquid line of decent. Owing to this sympathetic fractionation behavior, the primary, source-related Pb–Ba fingerprint (with weak or strong Pb enrichment) remains in evolved S-type granites. This facilitates a distinction between primary low-T S-type granites, which are related to muscovite melting, and secondary low-T S-type granites that evolve through fractional crystallization from a higher-T parental magma. We show in this paper that a simple logarithmic Pb versus Ba diagram can be a valuable aid for interpreting the petrogenesis of S-type granite suites.