湖北省罗田凤凰关混合岩浅色体的类型及其锆石U-Pb年龄

根据混合岩浅色体的重褶、横切和叠加关系并剔除因粘性褶皱效应引起的重褶皱假象，在湖北罗田凤凰关识别出８个世代的浅色体。它们的主量、微量和稀土元素地球化学研究表明，用于锆石Ｕ－Ｐｂ定年的浅色体是深熔成因的。锆石Ｕ－Ｐｂ定年结果表明，在大别杂岩内存在燕山期的混合岩化作用，其时代为（１２９．３．８）Ｍａ。     

秦岭杂岩中花岗质片麻岩体的岩石地球化学特征及成因

该片麻岩是目前秦岭杂岩中最古老的深成岩体，原岩岩性为（含斑）黑云母二长花岗岩，其地球化学特征是：ＳｉＯ２较高；Ａｌ２Ｏ３，ＣａＯ，Ｎａ２Ｏ大离子亲石元素及过渡性元素低；稀土总量变化大，轻稀土分馏明显，Ｅｕ为负异常（０．３１～０．６１）。岩体中所含的黑云母变粒岩包体在地球化学方面与主岩有明显互补性，为难熔残体。研究表明该古岩体是成分相当于秦岭杂岩的长英质变质岩的岩石于晋宁期下冲深埋过程中部分熔融的产物。     

大别杂岩中混合岩的矿物空间分布研究

介绍了矿物空间分布研究的基本原理及两种统计方法(接触频数法和线切法)。作者对混合岩矿物空间分布的研究表明:(1)前人提出的统计方法存在方法上的缺陷和应用上的局限性,作者推导出矿物接触类型的概率公式;(2)部分浅色体中矿物显示聚集分布的特征,而绝大部分的浅色体中矿物具有分散分布的特点。结合质量平衡和地球化学研究认为:大别杂岩中主体混合岩成因机制是重熔和交代作用。     

桐柏造山带深熔作用:混合岩LA-ICPNIS锆石U-Pb年代学证据

桐柏造山带是研究秦岭-桐柏-大别-苏鲁变质带演化的关健地区.由于桐柏高级变质杂岩深熔作用发生时间还缺乏准确的限定,这一区城的构造演化仍存在较大的争议.本文对桐柏杂岩中的一个混合岩的中色体和两个混合岩浅色体样品中的锆石进行了LA-ICPMS年代学测定.中色体中锆石分析点获得的上下交点分别为859±73Ma和135±250Ma.接近上交.4的6个谐和分析点给出的206 Pb/238 U加权平均结果为828±7Ma(MSWD=0.57).这一年龄结果同上交点在误差范围内一致,代表混合岩原岩结晶年龄,对应扬子板块北缘出现的中-新元古代的岩浆事件.另一方面,混合岩浅色体中的新生锆石具有面状分带或是弱的振荡环带,低的Tb/U比值,锆石形态学和内部结构也表明新生锆石结晶于与深熔作用有关的熔体中,它们的206 Pb/238 U加权平均值分别为135±4Ma和131±3Ma.这一年龄范围代表桐柏高级变质地体发生深熔作用时间,区城上与桐柏-大别变质带广泛出现的碰撞后岩浆事件的时代相同.桐柏造山带出现造山后伸展的时间应不晚于135Ma.     

华北克拉通阜平杂岩的深熔和混合岩化作用

华北克拉通的阜平杂岩长英质岩石中常产出显著的浅色体、岩脉和花岗岩侵入体,并形成广泛的混合岩化作用。通过矿物自形晶的形成、黑云母向角闪石的转换和大量钠长石净边的出现以及其它与熔体活动有关结构的分析,浅色脉体和混合岩化作用的发生与外来熔体的注入有关。在长英质片麻岩中可出现明显的熔体注入,在一些不易片理化的岩石如石英岩中亦可形成浸染状熔体渗入。熔体汇集可形成浅色体、岩脉,直至花岗岩侵入体。而深熔作用本身形成熔体的作用在本区几乎可以忽略不计。在遭受渗透式混合岩化作用的过程中,岩石成分发生了改变,形成开放系统。随着渗透熔体的结晶,可形成一些岩浆锆石,在副片麻岩中则很容易被当作碎屑锆石。     

试论阜平杂岩的深熔作用

阜平杂岩中广泛产出浅色脉体,从而显示强烈的混合岩化作用。前人把引起混合岩化作用的机制归因于岩汁交代、重熔或无水深熔作用,似乎与实际的岩相结构不是很一致。矿物自形晶、钠长石净边结构和一些典型的矿物转化反应表明,阜平杂岩的混合岩化作用实际上经历了复杂的过程,主要表现为有水条件下的深熔作用。所形成的熔体有较大的流动性,可迁移一定的距离而进入邻近的岩石,对这些部位而言相当于发生了外来熔体的注入活动,造成熔体注入式混合岩化作用,形成一些交代反应和结构。因此,阜平杂岩混合岩化作用中的变质反应过程既包括长英质矿物的熔融(溶解),还涉及一种含水矿物(如黑云母)转化形成另外一种含水矿物(如角闪石)的化学反应。阜平杂岩的混合岩化作用最重要的机制是水致熔融或含水深熔作用,溶解性重熔或无水深熔作用则较为次要。     

桐柏造山带深熔作用:混合岩LA-ICPMS锆石U-Pb年代学证据

桐柏造山带是研究秦岭-桐柏-大别-苏鲁变质带演化的关键地区。由于桐柏高级变质杂岩深熔作用发生时间还缺乏准确的限定,这一区域的构造演化仍存在较大的争议。本文对桐柏杂岩中的一个混合岩的中色体和两个混合岩浅色体样品中的锆石进行了LA-ICPMS年代学测定。中色体中锆石分析点获得的上下交点分别为859±73Ma和135±250Ma。接近上交点的6个谐和分析点给出的²⁰⁶Pb/²³⁸U加权平均结果为828±7Ma (MSWD=0.57)。这一年龄结果同上交点在误差范围内一致,代表混合岩原岩结晶年龄,对应扬子板块北缘出现的中-新元古代的岩浆事件。另一方面,混合岩浅色体中的新生锆石具有面状分带或是弱的振荡环带,低的Th/U比值,锆石形态学和内部结构也表明新生锆石结晶于与深熔作用有关的熔体中,它们的²⁰⁶Pb/²³⁸U加权平均值分别为135±4Ma和131±3Ma。这一年龄范围代表桐柏高级变质地体发生深熔作用时间,区域上与桐柏-大别变质带广泛出现的碰撞后岩浆事件的时代相同。桐柏造山带出现造山后伸展的时间应不晚于135Ma。     

黄山东镁铁超镁铁杂岩中的辉石化学成分研究

通过对黄山东镁铁超镁铁杂岩的辉石化学成分研究，证明辉石的化学成分受寄主岩石类型的制约，从超镁铁岩相到角闪辉长岩相斜方辉石的化学成分由富ＭｇＯ、ＳｉＯ＿２、Ａｌ＿２Ｏ＿３、Ｃｒ＿２Ｏ＿３到富ＦｅＯ、ＴｉＯ＿２、ＣａＯ、ＭｎＯ；单斜辉石化学成分由富Ａｌ＿２Ｏ＿３、Ｃｒ＿２Ｏ＿３、Ｎａ＿２Ｏ、ＭｇＯ到富ＦｅＯ、ＭｎＯ、ＣｏＯ。在同一寄主岩石中，单斜辉石比斜方辉石富ＴｉＯ＿２、Ａｌ＿２Ｏ＿３、Ｃｒ＿２Ｏ＿３、ＣａＯ和Ｎａ＿２Ｏ，贫ＭｇＯ、ＳｉＯ＿２、ＭｎＯ和ＦｅＯ。根据辉石化学成分特征得出黄山东杂岩形成于岛弧环境，为上地幔石榴二辉檄榄岩部分熔融形成的拉斑玄武岩岩浆结晶分异作用的产物。     

麻山杂岩的变质-混合岩化作用和花岗质岩浆活动

在黑龙江佳木斯地块麻山杂岩中可分别有高级和中级变质作用部分,两处均可见混合岩化作用。通过混合岩浅色脉体或花岗质脉体中的长石自形晶、斜长石周围的钠长石净边、黑云母向角闪石的转化等现象表明混合岩化作用主要表现为深部岩浆的注入,而不仅是高级变质之后的近原地深熔作用所致,高级变质与相关的深熔作用所致混合岩化在区域上的分布是有限的,集中于西麻山的高级区;而注入式混合岩化是普遍的,其产出可遍布所有麻山杂岩的出露区,在麻粒岩相和角闪岩相部位均可出现。早期麻粒岩相变质与后期混合岩化作用应是相互独立的构造或热事件;注入式混合岩化引起了中级变质作用和高级区的退变质作用,注入混合岩化作用的时代约为500Ma;中级变质作用是注入混合岩化的结果,而不是混合岩化的原因。与注入混合岩相关的花岗岩虽然表现出一些S型花岗岩的特征,但根据矿物组合、地化性质的综合分析,更可能是富钾及钾长石斑晶的钙碱性花岗岩类,属于I型花岗岩,形成于挤压向引张转化的过程中。麻山杂岩的变质与混合岩化特征表明,以西伯利亚古陆为中心的南部边缘发生了与冈瓦纳陆块内泛非事件类似的构造活动,只不过这里的规模略小,在变质之后迅速发生了构造体系的转换,而形成大量花岗质岩浆活动。     

论大别造山带中“罗田片麻岩杂岩”的构造属性

罗田片麻岩杂岩位于大别造山带腹地，东、西大别变质带之间，面积约６０００ｋｍ２。主要由一套花岗片麻岩系组成。它们经历过早期高角闪岩相至麻粒岩相变质和晚期低角闪岩相叠加变质。该杂岩的原始建造以古老变质变形侵入体为主，与其周边构造变质单元的原始建造迥然不同，后者皆为沉积型或火山－沉积型原始建造。罗田片麻岩杂岩与其周边环境的地质特征不一致，是个造山带规模的外来变质地体。其下存在广泛的低密度岩层，相当于混合岩化或花岗岩化的硅铝质岩系。罗田片麻岩杂岩是华南、华北陆块碰撞期间，可能曾经存在的古岛弧深成岩系发生深变质强变形，并在仰冲机制作用下，于　地壳深层次拼贴到高压／超高压碰撞混杂岩之上的，具有推覆体属性的构造岩片。     

Geological and Geochemical Evidence for Discriminating Anatectic and Subsolidus Migmatites in the Dabieshan Complex,Northeastern Hubei Province

Based on the geological and geochemical information about migmatites,the following lines of evidence have been proposed for discriminating the anatectic leucosome in the Dabieshan Complex:(1)its width is larger than that derived from the subsolidus genesis,cutting across regional foliation,thus giving rise to complicated folds and wider selvages;(2)it is composed of melanic and accessory minerals in addition to quartz and feldspars;(3)the significant dfference in anorthites of plagioclase between paleosome and leucosome;(4)temperature and pressure(P/T) conditions revealed by the mineral compositions and assemblages are over those for the onset of anatexis;and (5)it is enriched in the major elements(e.g.Al2O3.Fe2O3and TiO2)and immobile and incompatible elements(e.g.LREE,Th,Hf and Zr).Finally,by combining the geological and geochemical features with the statistical data for the spatial distribution of minerals and mass-balance in the migatites,it is concluded that anatexis is the cardinal mechanism of migmatization in the Dabieshan Complex.     

燕山地区褶皱冲断带和盆地中的晚侏罗世土城子组/后城组形成分析（英文）

高级变质-深熔作用中伴随有熔体的形成,在缺失流体的不一致熔融条件下,如果熔体的萃取不完全,原地结晶熔体与残留体之间可发生特殊的退变反应———逆(熔)反应,这种反应与进变质脱水熔融恰好相反。逆(熔)反应的最佳判断标志就是在浅色体和早期深熔过程中形成的不一致熔融相之间含水矿物组合的生长。逆(熔)反应形成的退变组合是深熔作用过程的一部分,而不是另外期次的变质事件叠加。逆(熔)反应的地质意义在于它可能会影响到熔体和流体组成、流体-岩石的相互作用以及对质量平衡的研究,尤其是对p-T路径恢复的影响,从而影响到构造和热流模型的推断。     

The genesis of wadi Magrish migmatites (N-E Sinai)

The migmatite complex of the Magrish area is part of a large crystalline massif south of Elat. The mineralogical composition of the migmatites is very uniform. The components of the melanosome are biotite, quartz and plagioclase, with small amounts of garnet and very rarely sillimanite and those of the leucosome — quartz and plagioclase. On the basis of chemical composition of the migmatites and possible premigmatitic parent rocks, absence of orthoclase in the leucosome, similar composition of plagioclase in the leucosome and in neighbouring melanosome, and Qz:Plag values which do not plot around a cotectic line, it is concluded that migmatisation occurred in a nearly closed system, without the presence of a melt phase. Thus, injection of granitic material, metasomatism or partial anatexis as possible main formation mechanisms are rejected and metamorphic differentiation is favoured.     

大陆造山带深熔垮塌的岩石学、地球化学证据:以北大别深熔混合岩为例

北大别位于大别造山带的核部,分布着大量的造山带垮塌时期形成的混合岩,其于理解大别造山带的形成和演化有着重要的意义。北大别混合岩的原岩为TTG（D）岩石,因黑云母和角闪石的脱水熔融诱发深熔作用产生。顺层产出的为富斜长石浅色体,主要矿物组成为斜长石+石英+黑云母±钾长石±角闪石。伟晶岩脉或团块为富钾长石浅色体,主要矿物组成为钾长石+石英±斜长石±黑云母±角闪石。暗色体为变晶结构,主要矿物组成为角闪石+黑云母+斜长石+石英±单斜辉石;其中,暗色矿物角闪石和黑云母常常定向排列,具有明显的溶蚀结构;暗色体中浅色矿物颗粒较小,以斜长石和石英为主,指示部分熔融的残余产物。全岩地球化学特征表明,碱金属元素（Na、K等）、大离子亲石元素（Ba、K、La等）和LREE等优先进入酸性熔体,而相容元素和中-重稀土元素等残留在残余体中。浅色体与本区花岗岩相比,二者都有右倾的稀土配分模式,富集LREE,亏损HREE。但浅色体具有明显的Eu正异常,δEu值为2.48~6.55,而花岗岩则有弱的Eu负异常,并且浅色体中大颗粒斜长石相互构成框架结构,含量明显高于正常花岗岩熔体,表明浅色体更可能是熔体早期结晶的产物。     

深熔成因伟晶岩初始岩浆中稀有金属富集特征

本文以新疆阿尔泰切木尔切克地区的混合岩和伟晶岩为例,开展区内混合岩、伟晶岩与周围的变沉积岩（二云母片岩）的野外地质、全岩地球化学以及云母类矿物化学组成研究,目的在于揭示深熔作用形成的熔体中稀有金属富集特征。研究结果显示,阿尔泰切木尔切克地区的伟晶岩与混合岩中浅色体有相似的矿物组合和主要化学组成,且伟晶岩与暗色体呈互补的微量元素组成,表明切木尔切克伟晶岩为变沉积岩深熔成因。从二云母片岩到混合岩中浅色体和伟晶岩,白云母中Li、Be、Nb、Ta、Rb、Cs显示增加趋势,表明深熔作用形成浅色体及其汇聚成伟晶岩脉过程中可促进稀有金属的富集,尤其是Be和Ta,富集程度达3倍以上。低温条件下白云母脱水熔融,导致黑云母作为残留相,明显制约Li、Rb、Cs等稀有金属在熔体中的富集,但对Be的影响非常有限。结合阿尔泰伟晶岩广泛的Be成矿作用,推断阿尔泰伟晶岩很可能是深熔成因的。     

Muscovite dehydration melting in Si-rich metapelites: microstructural evidence from trondhjemitic migmatites,Roded, Southern Israel

Making a distinction between partial melting and subsolidus segregation in amphibolite facies migmatites is difficult. The only significant melting reactions at lowpressures, either vapour saturated or muscovite dehydration melting, do not produce melanocratic peritectic phases. If protoliths are Si-rich and K-poor, then peritectic sillimanite and K-feldspar will form in scarce amounts, and may be lost by retrograde rehydration. The Roded migmatites of southern Israel (northernmost Arabian Nubian Shield) formed at P = 4.5 ± 1 kbar and T ≤ 700 °C and include Si-rich, K-poor paragneissic paleosome and trondhjemitic leucosomes. The lack of K-feldspar in leucosomes was taken as evidence for the non-anatectic origin of the Roded migmatites (Gutkin and Eyal, Isr J Earth Sci 47:117, 1998). It is shown here that although the Roded migmatites experienced significant post-peak deformation and recrystallization, microstructural evidence for partial melting is retained. Based on these microstructures, coupled with pseudosection modelling, indicators of anatexis in retrograded migmatites are established. Phase diagram modelling of neosomes shows the onset of muscovite dehydration melting at 4.5 kbar and 660 °C, forming peritectic sillimanite and K-feldspar. Adjacent non-melted paleosomes lack muscovite and would thus not melt by this reaction. Vapour saturation was not attained, as it would have formed cordierite that does not exist. Furthermore, vapour saturation would not allow peritectic K-feldspar to form, however K-feldspar is ubiquitous in melanosomes. Direct petrographic evidence for anatexis is rare and includes euhedral plagioclase phenocrysts in leucosomes and quartz-filled embayments in corroded plagioclase at leucosome-melanosome interfaces. In deformed and recrystallized rocks muscovite dehydration melting is inferred by: (1) lenticular K-feldspar enclosed by biotite in melanosomes, (2) abundant myrmekite in leucosomes, (3) muscovite–quartz symplectites after sillimanite in melanosomes and associated with myrmekite in leucosomes. While peritectic K-feldspar formed in melanosomes by muscovite dehydration melting reaction, K-feldspar crystallizing from granitic melt in adjacent leucosome was myrmekitized. Excess potassium was used in rehydration of sillimanite to muscovite.     

Trace element behaviour during migmatization. Evidence for a complex melt-residuum-fluid interaction in the St. Malo migmatitic dome (France)

The St. Malo migmatitic dome represents an interesting example wherein migmatites arise from the anatexis of the surrounding gneisses. Petrographical and chemical data suggest that leucosome compositions are compatible with partial melting of the quartzo-feldsphathic fraction of the parent gneiss. The contribution of the incongruent melting of biotite to the melt does not exceed 5% of the parent rock.Petrogenetic modelling based on experimental data and assuming non modal batch melting show that the K, Rb, Ca, Sr, U and Th chemical patterns of these migmatites result in fact from the interaction of several mechanisms, namely: equilibrium partial melting, mixing between melts and refractory minerals (biotite and accessories), melt removal and late hydrothermal alteration. Zr, Y and Th which are mostly hosted in accessory minerals are significantly withheld from the melts and remain stored in melanosomes (metatexites) except when leucosomes are affected by mixing (diatexites). U is frequently enriched in the leucosomes as well as in some melanosomes suggesting external supply.     

Petrogenesis of a Stromatic Migmatite (Nelaug, Southern Norway)

The stromatic migmatites of Nelaug (Tvedestrand area, SouthernNorway) are investigated in detail. They show well developedlayers of leucosomes, mesosomes and melanosomes. It is establishedthat the mesosomes and leucosomes of these migmatites are differentfrom each other texturally, mineralogically, and chemically.Also combinations of leucosome plus adjacent melanosome portionsare chemically different from those of the mesosomes. Theseobservations do not agree with the findings of Mehnert (1971)and do not fit into his genetic model. The mesosome layers and the leucosome + melanosome combinationsare taken to represent the chemical compositions of the countryrock, a metagraywacke with relicts of primary rhythmic layering(Touret, 1965). The mineralogical composition of the layersvaries from granitic to tonalitic. Relict textures indicatethat the leucosome portions were initially occupied by layersof granitic composition relatively rich in K-feldspar, whereasthe mesosomes are the representatives of those metagraywackelayers which were relatively rich in plagioclase. An almostisochemical transformation of a paragneiss into the investigatedstromatic migmatite is established. Melting experiments performed at PH₂O= 5 Kb yielded solidustemperatures of 640±7 °C for all layers. The Composition of plagioclases present in the different layersis explained by isochemical partial melting and in situ crystallization.The chemical, mineralogical, and textural findings support themodel of almost isochemical transformation already establishedfor the Arvika migmatites (Johannes & Gupta, 1982).     

Insights into the complexity of crustal differentiation: K2O‐poor leucosomes within metasedimentary migmatites from the Southern Marginal Zone of the Limpopo Belt,South Africa

Differentiation of the continental crust is the result of complex interactions between a large number of processes, which govern partial melting of the deep crust, magma formation and segregation, and magma ascent to significantly higher crustal levels. The anatectic metasedimentary rocks exposed in the Southern Marginal Zone of the Limpopo Belt represent an unusually well‐exposed natural laboratory where the portion of these processes that operate in the deep crust can be directly investigated in the field. The formation of these migmatites occurred via absent incongruent melting reactions involving biotite, which produced cm‐ to m‐scale, K₂O‐poor garnet‐bearing stromatic leucosomes, with high Ca/Na ratios relative to their source rocks. Field investigation combined with geochemical analyses, and phase equilibrium modelling designed to investigate some aspects of disequilibrium partial melting show that the outcrop features and compositions of the leucosomes suggest several steps in their evolution: (1) Melting of a portion of the source, with restricted plagioclase availability due to kinetic controls, to produce a magma (melt + entrained peritectic minerals in variable proportions relative to melt); (2) Segregation of the magma at near peak metamorphic conditions into melt accumulation sites (MAS), also known as future leucosome; (3a) Re‐equilibration of the magma with a portion of the bounding mafic residuum via chemical diffusion (H₂O, K₂O), which triggers the co‐precipitation of quartz and plagioclase in the MAS; (3b) Extraction of melt‐dominated magma to higher crustal levels, leaving peritectic minerals entrained from the site of the melting reaction, and the minerals precipitated in the MASs to form the leucosome in the source. The key mechanism controlling this behaviour is the kinetically induced restriction of the amount of plagioclase available to the melting reaction. This results in elevated melt H₂O and K₂O and chemical potential gradient for these components across the leucosome/mafic residuum contact. The combination of all of these processes accurately explains the composition of the K₂O‐poor leucosomes. These findings have important implications for our understanding of melt segregation in the lower crust and minimum melt residency time which, according to the chemical modelling, is <5 years. We demonstrate that in some migmatitic granulites, the leucosomes constitute a type of felsic refractory residuum, rather than evidence of failed magma extraction. This provides a new insight into the ways that source heterogeneity may control anatexis.     

Dynamic Mechanism of Migmatization in the Dabie Complex, Northeastern Hubei, China

On the basis of the detailed field work, compositions and contents of plagioclase and K - feldspar,determination of ordering degree, statistical analysis of plagioclase elongation index, mass-balance calculation and mineral spatial distribution and geochemistry, it is concluded that the migmatites in the Dabie complex are characterized by the presence of thermocenters. There are regular changes in mineral character in the migmatites from the centers outwards. The dominant genetic mechanism is anatexis and metasomatism, whose intensities decrease from the centers outwards. Finally, according to the simulated experiment on Liesegang' s rings and non-linear dynamics (dissipative structure theory), the dynamic mechanism of migmatization is profoundly expouded as consisting of the early-stage metasomatism induced by the thermal anomaly, the cardinal-stage anatexis induced by the early-stage matasomatism and finally the last-stage post-anatexis metasomatism.