共查询到20条相似文献,搜索用时 877 毫秒
1.
对中国东南部南岭地区出露的侏罗纪(燕山早期)花岗岩成因类型至今仍有不同认识.李献华等(2007)将南岭侏罗纪花岗岩的成因类型划分为:①铝质A型花岗岩;②型花岗岩;③分异Ⅰ型花岗岩.认为南岭广泛出露的含角闪石花岗闪长岩、黑云母花岗岩和二(白)云母花岗岩组成准铝质-弱过铝质的Ⅰ型/分异Ⅰ型花岗岩成因演化系列. 相似文献
2.
大兴安岭中南段燕山期三类不同成矿花岗岩中黑云母的化学成分特征及其成岩成矿意义 总被引:11,自引:1,他引:11
大兴安岭中南段燕山期三类不同成矿花岗岩中黑云母主要为富铁黑云母和铁黑云母,属富铁黑云母—铁叶云母系列。黑云母主要化学成分表明本区花岗岩碱度属正常碱度—过碱性岩石系列;本区燕山期花岗岩为壳幔混源成因,其岩石系列属于长江深源系列和南岭浅源系列之间的过渡类型。燕山期三个不同期次不同成矿系列的花岗岩中黑云母的化学成分明显不同。燕山早期早阶段与铜成矿有关的花岗岩黑云母相对以富镁贫铁为特征,燕山晚期早阶段与锡多金属矿化有关的花岗岩其黑云母成分相对以富铁贫镁为特征,燕山早期晚阶段与铅锌银矿化有关的花岗岩黑云母成分处于两者之间,黑云母的化学成分是判别本区三类不同成矿岩体的有效标志。 相似文献
3.
4.
湘南地区燕山期成矿花岗岩有3种类型,其主要造岩矿物化学成分和种属明显不同;矿物的化学成分变异特征均显示出壳幔岩浆混合成因的特点:①角闪石均属于钙质角闪石亚类。②MC型早期次花岗岩中的黑云母多属镁质黑云母;CM型晚期次花岗岩中的黑云母主要为铁质黑云母;C型花岗岩中的黑云母主要为铁叶云母-铁黑云母,且多为铁锂黑云母。3类型花岗岩中黑云母的成分变异呈线型关系,暗示有成因联系。③3类型花岗岩中斜长石有明显区别,MC型多为中长石,CM的多为更长石,C型多为钠长石。斜长石环带构造发育程度不同,CM型早期次单元花岗岩中的斜长石环带最发育。④CM型花岗岩及其暗色微粒包体中的碱性长石主要属于相对富钾的正长石,包体中的个别属歪长石,表明其形成温度较高;C型花岗岩中碱性长石为相对贫钾的钠正长石及微斜长石。⑤造岩矿物特征和成分变异显示了成矿花岗岩的形成与壳幔岩浆混合作用有关,形成MC型和CM型早期次单元花岗岩的岩浆演化主要是岩浆混合作用,而CM型花岗岩晚期次的花岗岩类和C型花岗岩类的岩浆演化可能还存在分离结晶作用。 相似文献
5.
藏东怒江板块结合带郭庆复式花岗岩体特征及其成因 总被引:1,自引:0,他引:1
根据作者在“三江”地区进行1∶20万洛隆幅区域地质调查工作中收集的资料,对产出于怒江板块结合带东侧的郭庆复式花岗岩体进行了解体,将岩体划分为燕山早期的黑云母二长花岗岩,燕山晚期的黑云母石英正长岩、黑云母花岗闪长岩三种岩石类型。通过对它们的地质学、岩石学、岩石地球化学特征的研究表明,这三种侵入岩分属陆壳改造S型花岗岩和壳幔同熔Ⅰ型中酸性岩。燕山早期花岗岩形成于同碰撞造山期,燕山晚期黑云母石英正长岩形成于板块碰撞后的抬升阶段,燕山晚期黑云母花岗闪长岩形成于造山晚期构造环境,是区内板块构造不同演化阶段的产物。郭庆复式岩体的形成与三江地区板块构造演化密切相关 相似文献
6.
湖南省花岗岩主要形成于加里东期、印支期和燕山期,分为"I"型和"S"型两个成因类型。其中"I"型花岗岩主要为角闪(或含角闪)石英闪长岩-花岗闪长岩-二长花岗岩,Mf值(铁镁比值)多小于0.78;"S"型花岗岩主要为黑云母(或二云母)二长花岗岩-钾长花岗岩,Mf值多大于0.78."I"型花岗岩与金矿的关系更为密切,于该类岩体内或其周围形成岩浆热液型或混合热液型多金属共生金及钨锑-金矿床。根据"I"型花岗岩与金矿关系的不同特点,将其划分为自源型金成矿"I"型花岗岩带和它源型金成矿"I"型花岗岩带。"S"型花岗岩与金矿的关系仅表现为部分岩体周围发育一定程度的金矿化。 相似文献
7.
佛冈高分异I型花岗岩的成因:来自Nb-Ta-Zr-Hf等元素的制约 总被引:12,自引:8,他引:4
华南南岭地区发育有大面积的与钨锡成矿相关的侏罗纪花岗岩,然而其中有些花岗岩的成因类型却难以确定。本文以佛冈岩体为例,结合前人已发表数据,对佛冈花岗岩体中Nb、Ta、Zr和Hf等元素的迁移特征及其原理进行探讨,并对佛冈花岗岩的成因类型进行了厘定。随着分异程度增加,佛冈花岗岩Nb和Ta含量增加,Nb/Ta(3.6~15.3)和Zr/Hf(17.3~38.9)比值降低并发生分异。随着Zr含量的降低,佛冈花岗岩的Zr/Hf比值降低,这一特征表明锆石的分离结晶作用使得佛冈花岗岩的Zr/Hf比值分异。Nb/Ta比值分异可能与角闪石和黑云母的分离结晶作用有关。随着Nb/Ta比值降低,Y/Ho比值增加,这一特征表明佛冈花岗岩Nb/Ta比值的分异也和岩浆演化后期的流体有关。佛冈花岗岩不含原生的富铝矿物,为准铝质到弱过铝质岩石。随着分异程度增加,佛冈花岗岩P2O5含量降低,表明它不是S型花岗岩。随着Y/Ho比值增加和Nb/Ta和Zr/Hf比值降低,佛岗花岗岩Ga/Al和Fe OT/Mg O比值增加,从典型I型花岗岩特征演化到类似A型花岗岩的地球化学特征。因此,我们认为佛冈花岗岩不是A型花岗岩而是高分异的I型花岗岩。区域上与成矿相关的流体和花岗质岩浆的相互作用和分离结晶作用,使得华南南岭地区的花岗岩地球化学特征复杂,所以其成因类型也变的难以确定。 相似文献
8.
华东地区燕山期花岗质岩浆与成矿作用关系研究 总被引:6,自引:2,他引:4
华东地区是我国重要的钨、铜、铁、钼、金、银、铀、铅、锌等多种金属矿产的产业基地。本文系统总结了华东地区钦杭成矿带和武夷山成矿带等重要多金属成矿带的燕山期岩浆活动与成矿作用的时空演化规律,提出燕山期区域成岩成矿作用可划分为早、晚两期四个阶段。(1)燕山早期早阶段(180~165Ma),以I型花岗岩及埃达克质岩石为主,主要分布在钦杭结合带东段以及武夷山成矿带的闽西南坳陷区内,形成一系列斑岩型及矽卡岩型铜铅锌银多金属矿床;其中埃达克质岩是俯冲板块挤压环境下加厚(或拆沉)下地壳重熔的产物;(2)燕山早期晚阶段(165~140Ma),以S型花岗岩以及钨锡、铌钽矿床为主,主要分布于南岭成矿带,另有少量非埃达克质I型花岗岩;(3)燕山晚期早阶段(145~120Ma),为区域由挤压向伸展过渡的构造转换期,在古太平洋板块斜向俯冲所导致的大规模伸展背景下,产生了S型与I-A型花岗岩共生的局面,其中S型火山-侵入杂岩与火山热液型铀铅锌矿床关系密切;在钦杭结合带东段一线出现A型花岗岩以及伴生的钨锡铌钽矿化,其年龄(135~125Ma)略晚于S型火山-侵入杂岩,在武夷山地区岩石类型则以I型为主,并与矽卡岩型以及石英脉型钨锡铁钼矿有关;(4)燕山晚期晚阶段(120~90Ma),在强烈的伸展背景以及俯冲带向洋迁移作用下,成岩成矿事件集中在武夷山以东的沿海地区,以出现晶洞花岗岩、过碱性花岗岩等高温、浅成、高分异花岗岩类为特征,但金属成矿作用则大多与富钾的I型花岗岩类有关,在多个矿集区内形成大量的浅成低温热液型铜金银矿床。钦杭成矿带和武夷成矿带之间的成岩-成矿时空差异性主要受控于古太平洋板块俯冲过程及基底物质组成。 相似文献
9.
南岭东段是我国有色、稀有、稀土、放射性矿产资源最富集的地区之一,尤其是石英脉型黑钨矿、热液成因铀矿和离子吸附型稀土矿,都与燕山期尤其是燕山早期的黑云母花岗岩类具有密切的成因联系。本文在前人研究的基础上,概述了南岭东段地层、构造和岩浆岩对矿产产出和分布的控制特点和规律,总结了南岭东段矿床类型、时空分布规律等基本特征,分析了南岭东段重要矿产的找矿前景和方向。强调南岭东段以广泛出露前寒武纪地层为特点,构造复杂,线性构造与环形构造均不同程度控矿,岩浆活动频繁,尤以花岗岩类最为发育,不同控矿因素制约不同矿种的发育。南岭东段矿产丰富,已发现58种矿产、543处小型以上规模矿产地,18种矿床类型,燕山期尤其是燕山早期成矿大爆发,内生矿床多围绕中酸性岩体分布,外生矿产则散布各地而以交通位置便利处工作程度较高。提出万洋山-诸广山钨锡萤石水热资源找矿远景区、崇余犹-三南钨锡稀土铅锌找矿远景区、兴国-于都-赣县钨锡稀土稀有铅锌银金萤石远景区等重要找矿远景区;指出继续加强热液成因铀矿、石英脉型黑钨矿及共伴生锡矿、离子吸附型稀土矿以及萤石、高岭土、地热等矿产的寻找和研究,加强深部和外围找矿,对于南岭东段的地质找... 相似文献
10.
11.
《Journal of African Earth Sciences》2008,50(2-4):148-167
The Bafoussam area in western Cameroon is part of the Central African Orogenic Belt. It is dominated by granitoids which belong to the Pan-African syn- to post-collisional post-650 Ma group. Syenogranites are predominant, but alkali-feldspar granite, monzogranite, quartz-monzonite and quartz-monzodiorite occur as well. Four granitoid suites, biotite granitoids and deformed biotite granitoids with amphibole, megafeldspar granitoids with megacrysts and two-mica granitoids with primary muscovite and igneous garnet are distinguished. The granites can be assigned to high-K calc-alkalic to shoshonitic series. The partly shoshonitic biotite granitoids are metaluminous to weakly peraluminous and can be labelled as a highly fractionated I-type suite. The megafeldspar granitoids are weakly peraluminous with I-type character whereas the two-mica granitoids are weakly to strongly peraluminous and belong to an S-type suite. Emplacement ages at 558–564 Ma for the two-mica granitoids have been dated from monazite by the EMP Th–U–Pb method.The REE in the biotite granitoids are moderately fractionated with (La/Lu)N = 23–38. Enrichment of Nb and Ta varies by one order of magnitude. The megafeldspar granitoids show homogeneous and strongly fractionated REE patterns with (La/Lu)N = 27–42. The primitive mantle-normalized element patterns are homogeneous with marked negative Ba, Nb, Ta, Sr, Eu and Ti anomalies. The two-mica granitoids are characterized by low to moderate total REE contents with strongly fractionated REE expressed by (La/Lu)N ranging from 7 to 59. The negative Nb and Ta anomalies are less significant. Nd and Sr whole-rock isotope data confirm different sources for the granitoid suites. The source of the I-type biotite granitoids was probably a juvenile mantle which has been variably metasomatized. The source of the I-type megafeldspar granitoids is characterized by juvenile mantle and lower crust components. Anatectic melts of the upper continental crust with variable contribution of lower continental crust or mantle melts can explain the heterogeneous isotopic signatures of the S-type two-mica granitoids. It is suggested that the melting of these sources was successively initiated by the rising isotherms during a syn- to post-collisional setting which followed a subduction. 相似文献
12.
Biotite granites and muscovite-bearing granites are dominant rock types of the widespread granites in SE China. However, their petrogenesis has been enigmatic. A combined study of zircon U–Pb dating and Lu–Hf isotopes, whole-rock element geochemistry and Sr–Nd–O isotopes was performed for three late Mesozoic granitic plutons (Xinfengjie, Jiangbei and Dabu) in central Jiangxi province, SE China. All the plutons are composed of biotite granites and muscovite-bearing granites that have been poorly investigated previously. The new data not only allow us to assess their sources and magma evolution processes, but also helps us to better understand the genetic link to the large-scale polymetallic mineralization in SE China. LA-ICP-MS zircon U–Pb dating shows that three plutons were emplaced in the Late Jurassic (159–148 Ma) and that the muscovite-bearing granites are almost contemporaneous with the biotite granites. The biotite granites have SiO2 contents of 70.3–74.4 wt% and are weakly to strongly peraluminous with ASI from 1.00 to 1.26, and show a general decrease in ASI with increasing SiO2. They have relatively high zircon saturation temperatures (T Zr = 707–817 °C, most > 745 °C) and show a general decrease in T Zr with increasing SiO2. They have high initial 87Sr/86Sr ratios (0.7136 to 0.7166) and high δ18O values (9.1–12.8‰, most > 9.5‰) and clearly negative ε Nd (T) (? 9.5 to ? 11.8) and ε Hf (T) (in situ zircon) (? 13.1 to ? 13.5). The muscovite-bearing granites have high SiO2 contents (74.7–78.2 wt%). They are also weakly to strongly peraluminous with ASI of 1.04–1.18 but show a general increase in ASI with increasing SiO2. They have relatively low T Zr (671–764 °C, most < 745 °C) and also show a general decrease in T Zr with increasing SiO2. The muscovite-bearing granites have high Rb (up to 810 ppm) and high (K2O + Na2O)/CaO (up to 270), Rb/Sr (up to 42) and Rb/Ba (up to 30) as well as low K/Rb (< 150, down to 50), Zr/Hf (< 24, down to 11) and Nb/Ta (< 6, down to 2). They show similar Nd–O–Hf isotopic compositions to the biotite granites with ε Nd (T) of ? 8.7 to ? 12.0, δ18O of 8.7–13.0‰ (most > 9.5‰) and ε Hf (T) (in situ zircon) of ? 11.3 to ? 13.1. Geochemical data suggest the origin of the biotite granites and muscovite-bearing granites as follows: Partial melting of Precambrian metasedimentary rocks (mainly two-mica schist) in the lower crust at temperatures of ca. 820 °C generated the melts of the less felsic biotite granites. Such primary crustal melts underwent biotite-dominant fractionation crystallization, forming the felsic biotite granites. Progressive plagioclase-dominant fractionation crystallization from the evolved biotite granites produced the more felsic muscovite-bearing granites. Thus, the biotite granites belong to the S-type whereas the muscovite-bearing granites are highly fractionated S-type granites. We further suggest that during the formation of the muscovite-bearing granites the fractional crystallization was accompanied by fluid fractionation and most likely the addition of internally derived mineralizing fluids. That is why the large-scale polymetallic mineralization is closely related to the muscovite-bearing granites rather than biotite granites in SE China. This is important to further understand the source and origin of biotite granites and muscovite-bearing granites in SE China even worldwide. 相似文献
13.
淡色花岗岩对深入理解造山带构造演化具有重要意义.哈尔里克山南麓小铺地区出露多种类型的淡色花岗岩脉,包括黑云母花岗岩、二云母花岗岩、含电气石花岗岩以及含石榴石花岗岩.岩石地球化学研究显示这些淡色花岗岩整体具有高硅(SiO2=73.22%~75.12%)、铝(Al2O3=13.59%~14.49%)、碱(ALK=7.11%~9.67%),低钛(TiO2=0.01%~0.14%)、铁(TFeO=0.26%~1.37%)、镁(MgO=0.09%~0.46%)、钙(CaO=0.46%~1.92%)的特点,属于弱过铝质钙碱性-钾玄岩系列岩石.其中黑云母花岗岩具有较高的CaO/Na2O比值(0.46~0.47)和低的Rb/Sr比值(0.31~0.33),指示其为砂质源岩经黑云母脱水熔融形成;二云母花岗岩和含电气石花岗岩具有较低的CaO/Na2O比值(0.11~0.31)和高的Rb/Sr比值(1.41~3.75),为泥质源岩经白云母脱水熔融形成;含石榴石花岗岩具有强烈的Eu负异常以及"海鸥状"稀土配分模式,为高分异型花岗岩.小铺淡色花岗岩初始岩浆温度较低(T=637~744℃),结合其野外地质特征,认为其形成可能与深部物质的折返、造山带的伸展垮塌有关.利用LA-ICP-MS微区原位锆石U-Pb定年获得黑云母花岗岩的形成时代为308.5±2.2 Ma,含电气石花岗岩的形成时代为307.8±2.3 Ma,二者在误差范围内近乎一致,指示哈尔里克地区在晚石炭世末处于伸展构造背景. 相似文献
14.
The Jurassic granitoids (200–164 Ma) are distributed in the Korean Peninsula due to the Paleo-Pacific plate subduction. Early Jurassic (200–182 Ma) granitoids are mainly distributed in the southern Korean Peninsula. By contrast, Early to Middle Jurassic (182–164 Ma) granitoids are distributed in the central Korean Peninsula. In this study, we report detailed petrology, zircon U–Pb ages, and whole-rock geochemistry from the Seoul–Uijeongbu and Pocheon–Gimhwa pluton units in the central Korean Peninsula. The Seoul–Uijeongbu unit is dominated by biotite granite, with minor porphyritic biotite and garnet-biotite granite while the Pocheon–Gimhwa unit consists of biotite granite and porphyritic biotite granite, garnet-biotite granite, and two-mica granite. Zircon U–Pb age from those granites gives 180–167 Ma. The granitoids in the Pocheon-Gimhwa unit formed through fractional crystallization from biotite granite and porphyritic biotite granite to garnet-biotite granite, and two-mica granite based on gradually decreasing their Nb/Ta, Zr/Hf, and Eu/Eu* ratios. The strongly fractionated granitoids are garnet-biotite granite and two-mica granite. The LILE enrichment, Ta–Nb, Sr–P, and Eu–Ti troughs, and Ba depletion in most granitoids are similar to those of granitoids due to the subduction in the arc environment. Thus, these Jurassic granitoids (180–167 Ma) are mainly peraluminous granites with moderate crystal fractionation corresponding to I-type granite. Alkali feldspar granite associated with ore mineralization occurs in the Gwanaksan pluton from the southwestern Seoul–Uijeongbu unit. The alkali feldspar granite displays distinct negative Eu anomaly with high contents of Rb, Hf, Cs, and Nb compared with other granites. These characteristics imply that alkali feldspar granite experienced strong hydrothermal activity leading to feldspar ore mineralization compared to the other granites. The formation of a wide range of moderately evolved peraluminous granitoids is presumed to be related to rapid flat-subduction during 182–164 Ma, and the mineralization-related alkali feldspar granite indicates the termination of Jurassic granitoid magmatism in the central Korean Peninsula. 相似文献
15.
Magnesium isotopic compositions, along with new Sr–Nd–Pb isotopic data and elemental analyses, are reported for 12 Miocene tourmaline-bearing leucogranites, 15 Eocene two-mica granites and 40 metamorphic rocks to investigate magnesium isotopic behaviors during metamorphic processes and associated magmatism and constrain the tectonic-magmatic-metamorphic evolution of the Himalayan orogeny. The gneisses, granulites and amphibolites represent samples of the Indian lower crust and display large range in δ26Mg from −0.44‰ to −0.09‰ in mafic granulites, −0.44‰ to −0.10‰ in amphibolites, and −0.70‰ to −0.03‰ in granitic gneisses. The average Mg isotopic compositions of the granitic gneisses (−0.19 ± 0.34‰), mafic granulites (−0.22 ± 0.17‰) and amphibolites (−0.25 ± 0.24‰) are similar, indicating the limited Mg isotope fractionation during prograde metamorphism from granitic gneisses to mafic granulites and retrograde metamorphism from mafic granulites to amphibolites. The Eocene two-mica granites and Miocene leucogranites are characterized by large variations in elemental and Sr–Nd–Pb isotopic compositions. The leucogranites and two-mica granites have their corresponding (87Sr/86Sr)i varying from 0.7282 to 0.7860 and 0.7163 to 0.7191, (143Nd/144Nd)i from 0.511888 to 0.512040 and 0.511953 to 0.512076, 207Pb/204Pb from 15.7215 to 15.7891 and 15.7031 to 15.7317, 208Pb/204Pb from 38.8521 to 39.5286 and 39.2710 to 39.4035, and 206Pb/204Pb from 18.4748 to 19.0139 and 18.7834 to 18.9339. However, they have similar Mg isotopic compositions (−0.21‰ to +0.06‰ versus −0.24‰ to +0.09‰), which did not originate from fractional crystallization nor source heterogeneity. Based on hornblende/biotite/muscovite dehydration melting reaction and Mg isotopic variations in two-mica granites and leucogranites with the proceeding metamorphism, along with elemental discrimination diagrams, Eocene two-mica granites and Miocene leucogranites could be related to hornblende dehydration melting and muscovite dehydration melting, respectively. Mg isotopic compositions of Eocene two-mica granites become heavier compared to the source because of residues of isotopically light garnet in the source; while those of Miocene leucogranites become lighter because of entrainment of isotopically light garnet from the source region. Thus, a new model for crustal anatexis and Himalayan orogenesis was proposed based on the Mg isotope fractionation in the leucogranites and metamorphic rocks. This model emphasizes a successive process from Indian continental subduction to rapid exhumation of the Higher Himalayan Crystalline Series (HHCS). The former underwent high-temperature (HT) and high-pressure (HP) granulite-facies prograde metamorphism, which resulted in the hornblende dehydration melting and the formation of Eocene two-mica granites; while the latter experienced amphibolite-facies retrogression and decompression, which resulted in the muscovite dehydration melting and the formation of Miocene leucogranites. 相似文献
16.
松潘造山带马尔康强过铝质花岗岩的成因及其构造意义 总被引:2,自引:0,他引:2
松潘造山带广泛出露印支期后碰撞型花岗岩类, 其中包括埃达克质花岗岩类、A型花岗岩和I型花岗岩, 但目前人们对该区印支期强过铝质花岗岩尚未有深入的研究.松潘造山带马尔康花岗岩属于强过铝质花岗岩(A/CNK=1.10~1.20), 其岩石类型主要为中粒二云母花岗岩和中细粒二云母花岗岩.利用LA-ICP-MS锆石U-Pb定年方法, 获得中粒二云母花岗岩的岩浆结晶年龄为208±2Ma, 中细粒二云母花岗岩的岩浆结晶年龄为200±2Ma.马尔康强过铝质花岗岩K2O/Na2O=1.13~1.75, 富Rb、Th和U, 贫Sr、Ba、Co和Ni等元素; 稀土元素组成上显示存在强到中等的负Eu异常(Eu/Eu*=0.15~0.65);全岩初始87Sr/86Sr比值(ISr) 为0.70712~0.71137, εNd (t) =-10.36~-8.43, 锆石εHf (t) =-11.8~-1.1.地球化学和Sr-Nd-Hf同位素组成一致表明, 它们的岩浆来自于地壳物质的部分熔融, 其中中粒二云母花岗岩的源岩类型主要为地壳中的泥质岩类, 而中细粒二云母花岗岩的源岩主要为地壳中的杂砂岩类.结合松潘带的地质背景、区域构造-岩浆事件及其岩浆岩的组合分析, 印支期岩石圈拆沉作用可以用来解释马尔康强过铝质花岗岩的形成机制.在松潘带, 印支期岩石圈拆沉作用导致软流圈物质上涌, 这不仅促使了加厚下地壳物质发生部分熔融, 如松潘带印支期埃达克质和I型花岗岩浆的形成, 而且还诱发了中地壳物质的部分熔融, 如马尔康强过铝质花岗岩的形成.这表明松潘带印支期岩石圈拆沉作用已使地壳不同层次发生部分熔融作用. 相似文献
17.
Summary The Palim granite, hosted by the metasedimentary country rocks in the Bastar tin province, is a heterogeneous pluton that
comprises hornblende granite, biotite granite and two-mica granite. Spherical inhomogeneous surmicaceous enclaves occur within
the granites with coarse grained cores of muscovite mantled by finer muscovite-quartz-biotite (± sillimanite) rims. Geochemical
features imply that the granites are highly evolved and geochemically distinct. Petrographic and geochemical considerations
point towards a transition from metaluminous I-type hornblende-bearing granite in the south to peraluminous volatile-enriched
S-type like lithologies (biotite and two-mica granites) towards north. Modeling of highly incompatible elements such as Nb
and Cs, implies 31 to 33% assimilated fractional crystallization of a melt with an initial composition close to that of the
hornblende granite to form the two-mica granite. Hornblende geobarometry, plagioclase-hornblende thermometry (in hornblende
granite) and phengite barometry (in two-mica granite), yield P-T estimates of 5–7 kb/725°–760 °C, and 6 kb/700 °C, respectively.
The study further implies that a genetic link exists between granite magmatism and the formation of tin pegmatites in the
region. The preponderance of peripheral pegmatites to the north-east of the Palim granite is regarded a result of outward
crystal-melt fractionation and tectonic tilting of the pluton.
Received October 21, 1999; revised version accepted December 12, 2000 相似文献
18.
V. E. Zagorsky 《Doklady Earth Sciences》2016,471(1):1134-1139
The Durulgui granite?pegmatite system unites the Dedova Gora granite massif and pegmatite field with the Chalotskoe beryl deposit. New geochronological data on micas from porphyric biotite granites, fine-grained biotite granites, two-mica granites, and Be-bearing pegmatites are discussed. The plateau age of 128.5(±1.5)–131.2(±1.5) should be considered as indicating the formation time of the granite?pegmatite system as a whole. The age of the system implies the possibility of its formation owing to several magmatic pulses. This assumption concerns porphyric and fine-grained biotite granites and two-mica and muscovite granites, the contact between which is locally sharp. At the same time, the succession “two-mica granites → muscovite granites → granite?pegmatites → microcline pegmatites → microcline?albite pegmatites → albite pegmatites” demonstrates gradual facies transitions between rocks, which indicates their emplacement during a single magmatic pulse. 相似文献
19.
南岭大东山花岗岩的形成时代与成因——SHRIMP锆石 U-Pb年龄、元素和Sr-Nd-Hf同位素地球化学 总被引:5,自引:1,他引:4
中国东南部南岭地区广泛出露以弱过铝质黑云母二长花岗岩和黑云母钾长花岗岩为主的燕山早期花岗质岩石,其成因有待进一步研究。大东山岩体岩性主要为黑云母二长花岗岩和黑云母钾长花岗岩,两个样品的SHRIMP锆石U-Pb 年龄为165±2 Ma 和159±2 Ma,与区域南岭系列的黑云母花岗岩的主要形成时代一致。花岗岩样品以高硅(SiO2 > 72%)、高钾(K2O/Na2O > 1.6)、富碱(K2O + Na2O = 7.36% ~ 9.31%)和弱过铝质(集中于ASI = 1.00 ~ 1.11)为特征。微量和稀土元素组成上,岩体富Rb, Th 和LREE,贫Ba, Nb, Sr, P 和Ti, Eu 负异常显著(δEu = 0.06 ~ 0.34)。多数样品的Zr,Ce, Nb 和Y 含量总和小于350×10-6,10 000 × Ga/Al 值低于典型的A 型花岗岩。同位素组成上,样品具有高I sr( 0.7123 ~ 0.7193)和低εN(d t)(-9.3~ -11.5)的特点,两阶段Nd 模式年龄为1.70~1.89 Ga ;与全岩εNd(t)不同,岩浆锆石的εHf(t)具有较大的变化范围(-3.5~ -11.8)。矿物学及地球化学结果表明大东山是一个高分异的I 型花岗岩岩体。岩体岩浆很可能是由元古代火成岩石部分熔融形成,并伴随有少量年轻或新生幔源物质的加入,岩浆上升侵位的过程中发生混合、结晶分异作用。 相似文献
20.
对江西中部新丰街花岗质岩体开展了岩相学、LA-ICP-MS锆石U-Pb年代学以及元素和Sr-Nd-Hf同位素地球化学研
究,并探讨了岩石成因及其构造意义。结果表明,新丰街岩体由二云母花岗岩和黑云母花岗组成;两者均形成于晚侏罗世
(~148 Ma);二云母花岗岩SiO2含量为75.71%~78.36%,为弱过铝质-强过铝质岩石,属高钾钙碱性系列,Mg#变化于0.26~
0.34,具有较低的Ga/Al比值(绝大部分<2.6×10-4) 和较低的Zr+Nb+Ce+Y含量(<350×10-6),全岩εNd(t)为-10~-8.2,锆石原
位εHf(t)为-15.7~-9.4;黑云母花岗岩SiO2含量为71.25%~74.41%,主要为准铝质-弱过铝质岩石,也属于高钾钙碱性系列,
Mg#变化于0.32~0.37,同样具有较低的Ga/Al比值(绝大部分<2.6×10-4) 和较低的Zr+Nb+Ce+Y含量(<350×10-6),全岩初始
87Sr/86Sr比值为0.7136~0.7153,εNd(t)为-10.0~-8.9,锆石原位εHf(t)值为-16.5~-10.9。通过综合研究认为二云母花岗岩具有S
型花岗岩特征,是由下地壳中变质泥岩在相对较低温度下发生部分熔融而形成的;黑云母花岗岩具有I型花岗岩特征,是由下
地壳中长英质火成岩在相对较高温度下发生部分熔融而形成的。岩体侵位于由古太平洋板块俯冲引起的陆缘弧构造环境。 相似文献