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1.
Sheila J. Seaman Helle Gylling John P. Hogan Frank Karner G. Christopher Koteas 《Contributions to Mineralogy and Petrology》2011,162(6):1291-1314
The Tunk Lake pluton of coastal Maine, USA is a concentrically zoned granitic body that grades from an outer hypersolvus granite
into subsolvus rapakivi granite, and then into subsolvus non-rapakivi granite, with gradational contacts between these zones.
The pluton is partially surrounded by a zone of basaltic and gabbroic enclaves, interpreted as quenched magmatic droplets
and mushes, respectively, as well as gabbroic xenoliths, all hosted by high-silica granite. The granite is zoned in terms
of mineral assemblage, mineral composition, zircon crystallization temperature, and major and trace element concentration,
from the present-day rim (interpreted as being closer to the base of the chamber) to the core (interpreted as being closer
to the upper portions of the chamber). The ferromagnesian mineral assemblage systematically changes from augite and hornblende
with augite cores in the outermost hypersolvus granite to hornblende, to hornblende and biotite, and finally, to biotite only
in the subsolvus granite core of the pluton. Sparse fine-grained basaltic enclaves that are most common in the outermost zone
of the pluton suggest that basaltic magma was present in the lower portions of the magma chamber at the same time that the
upper portions of the magma chamber were occupied by a granitic crystal mush. However, the slight variations in initial Nd
isotopic ratio in granites from different zones of the pluton suggest that contamination of the granitic melt by basaltic
melt played little role in generating the compositional gradation of the pluton. The zone of basaltic and gabbroic chilled
magmatic enclaves, and gabbroic xenoliths, hosted by high-silica granite, that partially surround the pluton is interpreted
as mafic layers at the base of the pluton that were disrupted by invading late-stage high-silica magma. These mafic layers
are likely to have consisted of basaltic lava layers and basalt that chilled against granitic magma to produce coarse-grained
gabbroic mush. Basaltic and gabbroic magmatic enclaves and gabbroic xenoliths are hornblende-bearing, suggesting that their
parent melts were relatively hydrous. The water-rich nature of the underplating mafic magmas may have prevented extensive
invasion of the granitic magma by these magmas, owing to the much greater viscosity of the granitic magma than the mafic magmas
in the temperature range over which magma interaction could have occurred. 相似文献
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3.
Mafic and Felsic Magma Interaction in Granites: the Hercynian Karkonosze Pluton (Sudetes, Bohemian Massif) 总被引:12,自引:0,他引:12
The Hercynian, post-collisional Karkonosze pluton contains severallithologies: equigranular and porphyritic granites, hybrid quartzdiorites and granodiorites, microgranular magmatic enclaves,and composite and lamprophyre dykes. Field relationships, mineralogyand major- and trace-element geochemistry show that: (1) theequigranular granite is differentiated and evolved by smalldegrees of fractional crystallization and that it is free ofcontamination by mafic magma; (2) all other components are affectedby mixing. The end-members of the mixing process were a porphyriticgranite and a mafic lamprophyre. The degree of mixing variedwidely depending on both place and time. All of the processesinvolved are assessed quantitatively with the following conclusions.Most of the pluton was affected by mixing, implying that hugevolumes (>75 km3) of mafic magma were available. This maficmagma probably supplied the additional heat necessary to initiatecrustal melting; part of this heat could have also been releasedas latent heat of crystallization. Only a very small part ofthe Karkonosze granite escaped interaction with mafic magma,specifically the equigranular granite and a subordinate partof the porphyritic granite. Minerals from these facies are compositionallyhomogeneous and/or normally zoned, which, together with geochemicalmodelling, indicates that they evolved by small degrees of fractionalcrystallization (<20%). Accessory minerals played an importantrole during magmatic differentiation and, thus, the fractionalcrystallization history is better recorded by trace rather thanby major elements. The interactions between mafic and felsicmagmas reflect their viscosity contrast. With increasing viscositycontrast, the magmatic relationships change from homogeneous,hybrid quartz diorites–granodiorites, to rounded magmaticenclaves, to composite dykes and finally to dykes with chilledmargins. These relationships indicate that injection of maficmagma into the granite took place over the whole crystallizationhistory. Consequently, a long-lived mafic source coexisted togetherwith the granite magma. Mafic magmas were derived either directlyfrom the mantle or via one or more crustal storage reservoirs.Compatible element abundances (e.g. Ni) show that the maficmagmas that interacted with the granite were progressively poorerin Ni in the order hybrid quartz diorites—granodiorites—enclaves—compositedykes. This indicates that the felsic and mafic magmas evolvedindependently, which, in the case of the Karkonosze granite,favours a deep-seated magma chamber rather than a continuousflux from mantle. Two magma sources (mantle and crust) coexisted,and melted almost contemporaneously; the two reservoirs evolvedindependently by fractional crystallization. However, maficmagma was continuously being intruded into the crystallizinggranite, with more or less complete mixing. Several lines ofevidence (e.g. magmatic flux structures, incorporation of granitefeldspars into mafic magma, feldspar zoning with fluctuatingtrace element patterns reflecting rapid changes in magma composition)indicate that, during its emplacement and crystallization, thegranite body was affected by strong internal movements. Thesewould favour more complete and efficient mixing. The systematicspatial–temporal association of lamprophyres with crustalmagmas is interpreted as indicating that their mantle sourceis a fertile peridotite, possibly enriched (metasomatized) byearlier subduction processes. KEY WORDS: Bohemian Massif; fractional crystallization; geochemical modelling; hybridization; Karkonosze 相似文献
4.
黑龙江省张广才岭南部早侏罗世花岗岩具有明显的岩浆混合特征。岩体中暗色微粒包体发育,主要为细粒闪长质岩浆包体,包体形态多样,与寄主岩呈截然、过渡关系。包体的矿物组合明显不平衡,如矿物具有定向排列的特点,斜长石发育自形环带并存在新、老两个世代,发育针状磷灰石。由电子探针对斜长石、角闪石和黑云母等矿物分析结果可知,寄主花岗岩和包体中各主要矿物含量基本一致。岩石地球化学特征研究显示,包体与寄主花岗岩关系密切,两者在稀土元素和微量元素方面也表现为明显的地球化学亲缘关系。这表明张广才岭南部早侏罗世花岗质岩石具有壳幔混合成因特征,暗色微粒包体是由较基性的地幔岩浆进入寄主岩浆中淬火结晶而成,花岗质岩浆的源区主要为新生的地壳物质。 相似文献
5.
桂东北里松花岗岩中暗色包体的岩浆混合成因 总被引:25,自引:0,他引:25
在桂东北姑婆山地区的里松花岗岩中,暗色包体广泛分布,包体的形貌、结构构造和矿物学特征表明,它们是岩浆快速冷凝结晶产物;主元素和微量元素组成说明它们属钾玄岩系列,其源岩具OIB型微量元素特征;包体与寄主花岗岩中锆石U-Pb年龄的相同性,排除了来源于深部固体岩石熔融残留体或浅部围岩捕虏体的可能性,而两种岩石化学成分、岩石结构暗色包体和寄主花岗岩在岩石结构和全岩Sr-Nd同位素组成方面的明显差别性,又排除了同源包体或析离体、堆积体的可能性。里松花岗岩在很多地质-地球化学特征上都介于里松暗色包体和姑婆山主体花岗岩之间,里松暗色包体的总体特征显示了岩浆混合成因,是里松暗色包体岩浆与姑婆山主体花岗岩岩浆发生混合时不完全混合的残留物。 相似文献
6.
南秦岭地体东江口花岗岩及其基性包体的锆石U-Pb年龄和Hf同位素组成 总被引:12,自引:10,他引:2
东江口花岗岩体位于商丹与勉略缝合带之间的南秦岭中部,其中存在大量基性暗色微粒包体.锆石的LA-MCICPMS联机U-Pb年代学分析表明,东江口岩体的形成年龄为223Ma,其包体锆石的结晶年龄为222Ma,与寄主岩体大致同时形成,指示秦岭造山带印支晚期岩石圈构造体制属性从挤压.伸展转变发生在220Ma左右.锆石的Lu-Hf同位素原位分析结果表明,南秦岭晚三叠纪花岗岩是壳幔混合作用的产物,亏损的幔源岩浆与南秦岭(或扬子)的基底地壳物质可能为南秦岭地区晚三叠纪花岗岩的源区物质,它们的形成起因于秦岭造山带在主造山期后发生的岩石圈拆沉作用.大约220Ma开始,南秦岭岩石圈构造应力性质从挤压向伸展构造体制转变,岩石圈发生拆沉作用,地幔软流圈物质上涌并底侵于下地壳,诱发下地壳物质的部分熔融,当岩浆沿构造薄弱带上升过程中,幔源岩浆与寄主岩浆发生成份的交换,两种岩浆混合过程中不完全混溶,最终形成寄主岩体和暗色基性微粒包体. 相似文献
7.
The Nimchak granite pluton (NGP) of Chotanagpur Granite Gneiss Complex (CGGC), Eastern India, provides ample evidence of magma interaction in a plutonic regime for the first time in this part of the Indian shield. A number of outcrop level magmatic structures reported from many mafic-felsic mixing and mingling zones worldwide, such as synplutonic dykes, mafic magmatic enclaves and hybrid rocks extensively occur in our study domain. From field observations it appears that the Nimchak pluton was a vertically zoned magma chamber that was intruded by a number of mafic dykes during the whole crystallization history of the magma chamber leading to magma mixing and mingling scenario. The lower part of the pluton is occupied by coarse-grained granodiorite (64.84–66.61?wt.% SiO2), while the upper part is occupied by fine-grained granite (69.80–70.57?wt.% SiO2). Field relationships along with textural and geochemical signatures of the pluton suggest that it is a well-exposed felsic magma chamber that was zoned due to fractional crystallization. The intruding mafic magma interacted differently with the upper and lower granitoids. The lower granodiorite is characterized by mafic feeder dykes and larger mafic magmatic enclaves, whereas the enclaves occurring in the upper granite are comparatively smaller and the feeder dykes could not be traced here, except two late-stage mafic dykes. The mafic enclaves occurring in the upper granite show higher degrees of hybridization with respect to those occurring in the lower granite. Furthermore, enclaves are widely distributed in the upper granite, whereas enclaves in the lower granite occur adjacent to the main feeder dykes.Geochemical signatures confirm that the intermediate rocks occurring in the Nimchak pluton are mixing products formed due to the mixing of mafic and felsic magmas. A number of important physical properties of magmas like temperature, viscosity, glass transition temperature and fragility have been used in magma mixing models to evaluate the process of magma mixing. A geodynamic model of pluton construction and evolution is presented that shows episodic replenishments of mafic magma into the crystallizing felsic magma chamber from below. Data are consistent with a model whereby mafic magma ponded at the crust-mantle boundary and melted the overlying crust to form felsic (granitic) magma. The mafic magma episodically rose, injected and interacted with an overlying felsic magma chamber that was undergoing fractional crystallization forming hybrid intermediate rocks. The intrusion of mafic magma continued after complete solidification of the magma chamber as indicated by the presence of two late-stage mafic dykes. 相似文献
8.
本文通过对广西大宁花岗闪长岩体及其中的暗色微粒包体的岩石学、微量元素及稀土元素地球化学、Rb—Sr同位素及微量元素初始比值等研究,认为该岩体中的暗色微粒包体属于幔源物质,同时提出了包体与主体花岗岩成因的上地幔—地壳相互作用模式,强调了花岗岩浆形成过程中系统的开放性及上地幔基性岩浆参与的重要性。 相似文献
9.
U-Pb ages and morphologies of zircon in microgranitoid enclaves and peraluminous host granite: evidence for magma mingling 总被引:3,自引:0,他引:3
M. A. Elburg 《Contributions to Mineralogy and Petrology》1996,123(2):177-189
Granites of the S-type Wilson's Promontory Batholith (Lachlan Fold Belt, Australia) contain zircons which are euhedral and
relatively large; their age is 395 Ma, which can be considered as the best available estimate of the crystallysation age of
the granites. Contrary to their dominance in other S-type granites of the Lachlan Fold Belt, very few zircon cores give inherited
ages, varying between 500 and 1700 Ma. Microgranitoid enclaves contained within the granites contain a zircon population that
is dominated by relatively small, anhedral or elongated crystals. These give ages that are indistinguishable from the crystallisation
age of the granite. Some enclaves, which are characterised by the presence of megacrysts, contain a proportion of larger,
euhedral zircons. These zircons give inherited ages similar to the zircons from the granitic host rocks. The data are in agreement
with a magma mingling origin for the microgranitoid enclaves. The large euhedral zircons are interpreted to have been introduced
into the “enclave magma” during a hybridisation event which also introduced quartz and plagioclase megacrysts into the magma.
The relatively high proportion of inherited cores within the “large” zircon population of the enclaves is related to the timing
of mixing between “enclave” and host magma. This mixing event took place before the majority of the magmatic zircons crystallised
in the granitic magma. The small, anhedral zircons within the enclaves crystallised during quenching of the globules of enclave
magma against the cooler granitic magma.
Received: 21 August 1995 / Accepted: 9 October 1995 相似文献
10.
文章报道了江西蔡江花岗质岩体中发现暗色微粒包体,以及这些包体的地质、岩相学、LA-ICP-MS锆石U-Pb年代学和元素地球化学特征。包体多呈椭圆状,显示淬冷边和反向脉,具有典型的岩浆结构并含有针状磷灰石,有的包体含有长石捕虏晶。包体具有相对较低的SiO2(低至57.05 wt%)和较高的MgO+Fe2O3(高达14.21 wt%)含量。LA-ICP-MS锆石U-Pb定年数据表明,包体形成于晚三叠世(224 Ma),与寄主花岗岩(230~228 Ma)在误差范围内基本一致。上述特征表明,包体是离散的幔源偏基性岩浆团或者是幔源与寄主岩浆混合的产物。原始包体岩浆属于超钾质岩浆,可能是通过岩石圈地幔中交代成因的金云母辉石岩脉发生部分熔融而形成的。暗色微粒包体的发现为幔源岩浆底侵提供了直接证据,从而为蔡江花岗质岩石形成于较高温度提供佐证。该研究对于进一步探讨华南印支期花岗岩形成的热源机制具有意义。 相似文献
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东昆仑东段香加南山花岗岩基中加鲁河中基性岩体形成时代、成因及其地质意义 总被引:2,自引:0,他引:2
东昆仑东段香加南山花岗岩基中加鲁河中基性岩体主要岩石类型包括角闪辉长岩和石英闪长岩。LA-ICP-MS锆石U-Pb同位素定年结果显示加鲁河中基性岩体的结晶年龄为220 Ma。岩体SiO_2含量较低,为47.91%~58.92%,Al_2O_3含量为15.54%~18.35%,Na2O为1.70%~3.34%,K_2O为0.58%~1.92%,Na_2O/K_2O比值为1.34~2.93,平均1.92,MgO含量为3.69%~8.24%,Mg~#为46~61,铝饱和指数A/CNK介于0.70~0.90之间,主体属于准铝质中钾钙碱性系列。岩体富集轻稀土元素,亏损重稀土元素,具明显的Eu负异常(δEu=0.40~0.59);微量元素富集Rb、Th、Ba等大离子亲石元素(LILE),亏损Nb、Ta、Ti等高场强元素(HFSE)。岩石学和地球化学研究显示岩体在地壳深部和浅部经历了两次岩浆混合作用。在深部,幔源岩浆底侵作用使下地壳部分熔融形成长英质岩浆,两种岩浆不同比例混合,经过化学扩散均一化,从而具有相似的同位素特征和岩石地球化学特征。在地壳浅部,经深部混合的岩浆注入花岗质岩浆,岩浆边部同花岗岩完全混合形成加鲁河岩体中石英闪长岩,不完全混合则形成暗色微粒包体。对加鲁河中基性岩体研究表明,东昆仑东段在晚三叠世处于古特提斯演化的后碰撞阶段,在这一时期存在岩浆底侵事件。 相似文献
12.
《International Geology Review》2012,54(10):1150-1162
Late Cretaceous calc-alkaline granites in the Gyeongsang Basin evolved through the mixing of mafic and felsic magmas. The host granites contain numerous mafic magmatic/microgranular enclaves of various shapes and sizes. New SHRIMP-RG zircon U–Pb ages of both granite and mafic magmatic/microgranular enclaves are 75.0?±?0.5 Ma and 74.9?±?0.6 Ma, respectively, suggesting that they crystallized contemporaneously after magma mixing. The time of injection of mafic melt into the felsic magma chamber can be recognized as approximately 75 Ma by field relations, petrographic features, geochemical evolution, and SHRIMP-RG zircon dating. This Late Cretaceous magma mixing event in the Korean Peninsula was probably related to the onset of subduction of the Izanagi (Kula)–Pacific ridge. 相似文献
13.
Magma Mixing and the Production of Compositional Variation within Granite Suites: Evidence from the Granites of Southeastern Australia 总被引:15,自引:3,他引:15
Granite suites are groups of plutons possessing characteristicfeatures that are a result of their derivation from source materialof a specific composition. Variation within suites has beenascribed to a variety of processes. Magma mixing or minglingis a popular hypothesis, generally proposed in terms of blendingbetween a crustal melt and mafic material from the mantle thatcaused that melting. When the compositions of pairs of suitesfrom the Bega Batholith of southeastern Australia are compared,any differences seen at either end of the range in compositionare also seen at the other limit, so that both the most maficand most felsic rocks show similar relative abundances of particularelements. Similar relationships are seen for other granitesin the region. These observations are not consistent with large-scalemagma mixing or mingling and, although those processes may operateon a small scale, they cannot have been responsible for themajor compositional variations. Likewise, assimilation of countryrocks had no significant role in producing variation in thegranites of southeastern Australia. The production of variationby differential separation of melt from residual solid sourcematerial, or restite, must be favoured for many of the granitesuites of this region. KEY WORDS: assimilation; enclaves; granite suites; magma mixing; restite 相似文献
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15.
Isotopic evidence for multiple contributions to felsic magma chambers: Gouldsboro Granite, Coastal Maine 总被引:1,自引:0,他引:1
The Gouldsboro Granite forms part of the Coastal Maine Magmatic Province, a region characterized by granitic plutons that are intimately linked temporally and petrogenetically with abundant co-existing mafic magmas. The pluton is complex and preserves a felsic magma chamber underlain by contemporaneous mafic magmas; the transition between the two now preserved as a zone of chilled mafic sheets and pillows in granite. Mafic components have highly variably isotopic compositions as a result of contamination either at depth or following injection into the magma chamber. Intermediate dikes with identical isotopic compositions to more mafic dikes suggest that closed system fractionation may be occurring in deeper level chambers prior to injection to shallower levels. The granitic portion of the pluton has the highest Nd isotopic composition (εNd = + 3.0) of plutons in the region whereas the mafic lithologies have Nd isotopic compositions (εNd = + 3.5) that are the lowest in the region and similar to the granite and suggestive of prolonged interactions and homogenization of the two components. Sr and Nd isotopic data for felsic enclaves are inconsistent with previously suggested models of diffusional exchange between the contemporaneous mafic magmas and the host granite to explain highly variable alkali contents. The felsic enclaves have relatively low Nd isotopic compositions (εNd = + 2 – + 1) indicative of the involvement of a third, lower εNd melt during granite petrogenesis, perhaps represented by pristine granitic dikes contemporaneous with the nearby Pleasant Bay Layered Intrusion. The dikes at Pleasant Bay and the felsic enclaves at Gouldsboro likely represent remnants of the silicic magmas that originally fed and replenished the overlying granitic magma chambers. The large isotopic (and chemical) contrasts between the enclaves and granitic dikes and granitic magmas may be in part a consequence of extended interactions between the granitic magmas and co-existing mafic magmas by mixing, mingling and diffusion. Alternatively, the granitic magmas may represent an additional crustal source. Using granitic rocks such as these with abundant evidence for interactions with mafic magmas complicate their use in constraining crustal sources and tectonic settings. Fine-grained dike rocks may provide more meaningful information, but must be used with caution as these may also have experienced compositional changes during mafic–felsic interactions. 相似文献
16.
小兴安岭晚石炭世花岗岩岩浆混合作用的岩相学证据及其地质意义 总被引:7,自引:0,他引:7
小兴安岭晚石炭世花岗岩具有明显的岩浆混合特征。岩体中暗色岩浆包体发育,主要为细粒闪长质岩浆包体,包体形态多样、大小不一,与寄主岩石呈截然、模糊或过渡关系。包体的矿物组合明显不平衡,如出现了寄主岩石中的碱性长石捕虏晶,有时可见其具暗色矿物镶边,发育针状磷灰石。这表明小兴安岭晚石炭世花岗岩的岩浆混合表现为基性岩浆和酸性岩浆的混合。这为探讨这些花岗岩的成因提供了岩石学依据,同时也暗示晚古生代佳木斯—松嫩古陆可能发生过地壳的垂向生长。 相似文献
17.
《Journal of South American Earth Sciences》2000,13(1-2):67-78
Twenty-five mafic microgranular enclaves of the Lavras Granite Complex in southern Brazil were studied petrographically and geochemically to establish their origin and to investigate the processes involved in their differentiation. Mesoscopic and microscopic textures indicate that they are products of magma mingling between a basic end member of probable mildly alkaline affinity and host shoshonitic and alkaline granitic rocks. The hybridisation process involved at least the following mechanisms: (i) chemical diffusion of volatiles and very mobile elements such as K to the less polymerised liquids, leading to the crystallisation of hydrated mafic minerals; (ii) chemical diffusion of Ti and P to the less polymerised liquids, leading to titanite and apatite crystallisation; (iii) mechanical accretion in the basic magma of early crystallised host granite phases that promoted enrichment of their major constituents and of trace elements with high partition coefficients in these phases; (iv) chemical diffusion of elements such as Rb, Nb, Y, and Yb with high Kd in the major enclave phases, from host magma into the basic enclaves. These processes occurred simultaneously, probably before the dispersion of basic batch magma forming the mafic microgranular enclaves, and caused hybridisation and complex geochemical patterns. The patterns are very different from the linear trends predicted for near-equilibrium systems such as those of magma mixing or fractional crystallisation. 相似文献
18.
Baerzhe Be–Nb–Zr–REE deposit is hosted in alkaline granite (125 Ma) which intrudes in the late Jurassic Baiyingaolao Formation in the middle of the Great Hinggan Metallogenic Belt in China. The ore‐forming granite consists of three lithological facies: arfvedsonite‐bearing alkaline granite at the bottom, aegirine‐bearing albite aplite in the middle and pegmatite crust on the top. The albite aplite is the main orebody. We recognized three magmatic‐hydrothermal stages: orthomagmatic stage, late‐magmatic stage and hydrothermal stage, with the late‐magmatic stage being divided into two substages, the pegmatite substage and the aplite substage. Petrographic study on the granite, the microthermometric study on fluid inclusions and in situ laser‐ablation inductively coupled plasma mass spectrometry analysis for quartz‐hosted melt inclusions reveal the process of magmatic‐hydrothermal evolution. The finding indicates that primary magma evolved to more peralkaline by fractional crystallization, with synchronously increasing high field strength elements. An extremely high content of Zr and Nb are in the melt inclusions from last stage albite aplite (Zr, min 52 548 ppm, and Nb, min 4104 ppm). This implies that the residual magma directly formed the orebody of rare metal elements. Meanwhile, volatility was increasing during the magma evolution process and F‐bearing aqueous fluid was oversaturated at temperatures higher than 800°C. The separation of fluid from magma caused Li‐REE enrichment in F‐bearing fluid and depletion in residual melt, and led to the difference of the Y/Ho ratio between whole rock compositions and melt inclusion data. Fluid separated into a high‐salinity liquid and a low density vapor phase above 697°C, and enriched REE in the high‐salinity liquid. The oxygen isotope data shows mixing between primary magmatic‐hydrothermal fluid and meteoric water. The ubiquitous pseudo‐secondary fluid inclusions have a wide range of salinity below 462°C, which is similar to the melting temperatures of REE‐bearing daughter minerals. A model involving the mixing by meteoric water could be a mechanism for precipitation of REE minerals. 相似文献
19.
《Journal of Structural Geology》1999,21(8-9):1125-1130
Integrated studies that correlate gravity data with magmatic structures or geochemical analysis reveal that the organization of granitic plutons (shape and feeder) varies according to the tectonic regime (brittle or ductile) and type (extension, strike-slip or compression) under which magma was generated. Deformation clearly controls granite emplacement. It also has influence during the ascent, segregation of melt and indirectly during the phase of initial melting. Because of the contrast of viscosity between melt and its plastic matrix, strain partitioning develops during magma ascent that facilitates melt flow, which bears consequences for the chemical evolution of the magma. Fast rate of melt extraction out of the source may lead to chemical disequilibrium. At a larger scale, petrochemical zoning of plutons is described as a dynamic process that results from the competition between the rate of magma emplacement (the rate of the room provided by deformation) and the rate of magma delivery. 相似文献
20.
S- and I-type granites from the Lachlan Fold Belt, southeastern Australia, have been investigated to assess the role of disequilibrium melting in their petrogenesis. Differences between the median initial εHf compositions of magmatic zircon populations and the host bulk-rock (ΔεHfblk-zrc) range from −0.6 to +2.5 ε units, providing evidence for intra-sample (and hence inter-phase) Hf-isotopic heterogeneity. Linear variations on Harker diagrams and O and Hf isotope compositions of magmatic zircon preserved in many I- and S-type granites are inconsistent with assimilation or simple mixing hypotheses. In contrast, isotopic disequilibrium between the melt and a restite assemblage can explain the bulk-rock versus zircon differences observed in these samples.Assuming that magmatic zircon records the melt composition, differences between the bulk-rock εHf and εHf of magmatic zircon (ΔεHfblk-zrc values) measured for I-type granites (0.4–2.5) can largely be explained by disequilibrium amphibole dehydration melting of meta-igneous protoliths that were either isotopically heterogenous at the time they were formed, or perfectly homogeneous before being aged in the crust for 0.4–1.0 billion years prior to partial melting. The Currowong Suite exhibits petrographic features and preserves geochemical and isotopic compositions that do not lend themselves to simple restite model or magma mixing explanations; however, these observations could be explained by the restite unmixing of magma batches generated from a single source rock if, as modelling has suggested, separate batches contain different melt compositions.By investigating the application of disequilibrium melting to granite genesis, this study demonstrates that isotopic heterogeneity at various sampling scales should actually be expected for the production of granites from a single source, rather than necessitating the involvement of multiple sources and mixing processes. As a result great care should be taken in the interpretation of isotope data from granitic bulk-rocks or their zircons. 相似文献