Zircon U-Pb age, Lu-Hf Isotopic Characteristics and Origin of the Banshanping Granitoid Rocks in East Qinling Orogenic Belt

The Banshanping granitoid rocks distribute in the east of the North Qinling orogenic belt.It is a diorite-quartz diorite-granodiorite-granite series,spreading in a NW-SE direction,and intrudes into the Erlangping Group.The SiO2 content ranges from 57.04% to 76.56%,Na2O from 2.05% to 4.65%,K2O from 0.84% to 3.40%.Major element characteristics indicate that Banshanping granitoid rocks have properties of I type granotoids.SREE ranges from 36.51 ppm to 473.25 ppm,and LREE/ HREE ratios lie between 3.95 and 22.18.Negative Eu anomalies are not obvious in most samples,though there are obvious Nb,P and Ti positive anomalies.The zircon LA-ICP-MS ages of Banshangping granitoid rocks are 496.0±8.1 Ma-486.9±9.3 Ma.Hf isotope shows that 176Hf/177Hf ratios range from 0.282721 to 0.282876,εHf（t） values from 8.5 to 14,all positive,and corresponding modal ages （TDM2） range from 559 Ma to 908 Ma.Based on Hf isotope characteristics and existing SmNd and Rb-Sr isotope data,we consider that the Banshanping granitoid rocks originate from mantlederived material,i.e.the igneous rocks that formed in Neoproterozoic,and there may be a certain amount of crust-derived material during the formation of Banshanping granitoid rocks.

Origin and geochemistry of Pan-African granitoid rocks in the Gabal Um Shomer area,Southwestern Sinai,Egypt

Geological, petrological and geochemical studies indicated that there are two distinct types of granitoid rocks: older quartz diorites to granodiorite assemblage and younger granitoids, the latter occurring in two phases. The older granitoids have a meta-aluminous chemistry and a calc-alkaline character, with high MgO, Fe2O3, TiO2, CaO, P2O5, Sr and low SiO2, K2O, and Rb. Their major and trace elements data, together with low 87Sr/ 86Sr ratios (0.7029±0.0008) are indicative of I-type affinities. The second- and third-phase granitoids range from calc-alkaline to alkaline, respectively. The second-phase granitoids have a peraluminous chemistry and high Sr, Ba, CaO, MgO, Al2O3 and Ti2O and low SiO2, K2O, Nb, Y and Rb relative to the third-phase granitoids. The corundum normative nature and field observations suggested that it was formed by partial melting of the lower crust. The third-phase granitoids are alkaline in nature and characterized by higher SiO2, Rb, Y, Nb and lower MgO, Sr and Ba values than the younger granitoids (phase Ⅱ). They are A-type granitoids which were generated from below or within the existing continental crust.

GRANITOIDS,VOLCANIC ROCKS AND CHERTS FROM NORTH ALTYN TAGH,NW CHINA: IMPLICATION FOR THE TECTONIC ENVIRONMENT DISCRIMINATION

Granitoids,volcanic rocks and cherts,mainly of early Paleozoic,in northern Altyn Tagh(Fig.1) are analyzed here for the purpose of the determination of the tectonic environments and their development since Early Paleozoic.(1) Granitoids\ The collection of 128 main\|element petrochemical data from North Altyn Tagh area shows that most of the granitoids here are granites and granodiorites of calc\|alkaline series.They consist mainly of metaluminous and peraluminous in Shand’s index,and only one of them,which belongs to Mesozoic,is peralkaline.Most of the granitoids plot in the IAG+CAG+CCG fields in the Maniar and Piccoli’s diagrams (1989) for tectonic discrimination of granitoids.IAG (Island arc granitoids)and CAG (Continental arc granitoids) can be distinguished for Early and Late Paleozoic granitoids,and maybe some CCG (Continental collision granitoids) for Early Paleozoic.Granitoids of Mesozoic and Cenozoic inherited the characteristics of those of Paleozoic.Destructive active plate margin (pre\|plate collision)and Anatectic magmatism(syn\|orogenic,S\|type granites)are distinguished (Fig.2)for Paleozoic granitoids using de la Roche R 1\| R 2 multicationic diagram (Batchelor and Bowden,1985).Mesozoic and Cenozoic granitoids inherited the characteristics of Anatectic magmatism (syn\|orogenic)of these early ones,and post\|orogenic(A\|type)granites occurred in Mesozoic.The mechanism for magma formation is mainly partial melting.

Geochemistry of Granitoid Rocks and Crustal Evolution, Zhejiang Province, China-Ⅱ.Proterozoic Granitoid Rocks

Proterozoic granitoid rocks in Zhejiang Province were formed in the Shengongian period (1. 8-1.9 Ga) and the Late Jinningian period (0. 6 -0. 9 Ga), respectively. Petrogenetic problems are discussed based on chemical (major, trace elements and REEs) and Nd-Sr isotopic compositions. The Shengongian granites resulted from partial melting of the Badu Groupand the Late Jinningian granites are of mantle dedvation with or without conednation of Crustalmaterial. The crust in Zhejiang had undergone three major periods of growth during 2. 6 - 2. 7Ga,0. 8 - 1. 1 Ga and 0. 10 - 0. 12 Ga after it was generated in Archean time. Compositional fractionation in the process of crust evolution is not evident. The presence of Late Jinningian granites of mantle- and man tie-crust-derivation along the JiangShan-Shaoxing Fault is indication ofcrust subduction at that time.

Geochemistry of Granitoid Rocks from Zhejiang Province and Crustal Evolution──Ⅰ.Phanerozoic Granitoid Rocks

The Phanerozoic granitoid rocks include the Caledonian, Indosinian and Yenshaniangranitoid rocks. The existence of Caledonian and indosinian granites was evidenced by zirconU-Ph ages. The study of the characteristics of major, trace and rare-earth elements, isotopiccompeition and petrogenesis for the granitoid rocks has been made. The Caledonian and Indosinian granites were derived from partial melting of the Proterozoic basement rocks and thetwo tectonic activities were weak. The Yenshanian granitoid rocks were derived from mixing of mantle and crustal materials. It implies that the Crustal accretion took Place in Mesozoic time.

Rock Series and Genetic Types of Granitoids in the Western Kunlun Orogenic Belt,China

A systematic geological and geochemical study was conducted for the granitoids of different periods in the western Kunlun orogenic belt. The study indicates that the granitoids belong to tholeiitic, calc-alkaline, high-K calc-alkaline, alkaline and shoshonitic series, and that there are 5 genetic types, i.e., I-, S-, M-, A- and SH-type, of which SH-type is first put forward in this paper, which corresponds to shoshonitic granitoids.

The Distribution of Trace Elements in Granitoids in the Nanling Region of China

Granitoids are widely spread in the Nanling Region of China.Four rockbodies in the region the been studied for their REE,Rb,Sr,Ba and Sc distributions.The four rockbodies occurred in different locations and are characterized as being different in age and type.The rock types are presented as follows:Qinghu monzonite,Guangxi;Fuxi granodiorite,Guangdong;Jiufeng monzonitic granite,Hunan;Zudong K-feldspar granite,Jiangxi.From the major and trace element distributions in these granitoids it is clearly shown that Rb/Sr ratios in the rocks tend to increase with increasing SiO2 content and differentiation index(DI),but LREE/HREE,La/Yb and K/Rb ratios tend to decrease,suggesting a correlation between trace element distribution and major element composition for the granitoids.The distribution characteristics of trace elements in each of the rockbodies are described in detail.From the comparative analysis of the Qinghu monzonite and Fuxi granodiorite it is evidenced that the REE distribution is closely related to the sequence of crystallization for the minerals,and also to the petrochemical types of these granitoids in addition to their crystal chemistry.

Geochronology and Petrogenesis of Mesozoic Granitoids in the Geological Corridor of Western Liaoning Province, China

The geological corridor of Western Liaoning province is an area of length 100 km and width 20 km and located in the eastern segment of northern margin of North China Craton（NCC）,with the wide distribution of Mesozoic granitic magmatism.It is the ideal area to study the granitic petrogenesis,the nature of magma source and the tectonic attribute.In this paper,we do the systematic researchesaboutthepetrology,geochronology,geochemistry and Zircon Hf isotopic of granitic rocks.Based on the mentioned above,we have built the geochronological framework and have discussed the petrogenesis,the nature of magma source and the tectonic setting of granitic rocks.And according to the information about the crust-mantle interaction recorded in granitic rocks and the regional data,we also discuss the relationship between Mesozoic granitic magma activities and lithosphere thinning,destruction of Craton mechanism in the eastern segment of northern margin of NCC.The Mesozoic granitic magma activities in The geological corridor of Western Liaoning province are divided into four stages（Fig.1）:Late Triassic（230 Ma;28 Ma）,early-middle Jurassic（194 Ma;69 Ma）,Late Jurassic（161 Ma;55 Ma）and Early Cretaceous（139Ma;21 Ma）.The late Triassic granitic rocks are composed of adamellite,monzogranite and diorite.The samples have high Sr,Cr,Ni content and low Yb,Y content,and the sample have high Mg#and high ratio of Sr/Y and La/Yb.The characteristics of inhomogenous negative value ofεHf（t）(-6.40;0.19)in magmatic zircons and ancient crustal TDM2 values of 1.25 Ga;.67 Ga（Fig.2）,indicate that the Triassic granitic rocks were formed in a post-collisional extensional tectonic setting aftersubduction of Paleo-Asian Ocean and the subduction of Yangtze Craton,and they are the product of partial melting of ancient lower crust under the condition of the mantle-derived magma underplating,and geochemical features of the high Sr and low Y are inherited from the source of magma which is also enriched in Sr and depleted in Y.The geochemical features and assemblages of rocks formed during Jurassic-early Cretaceous are similar.The early-middle Jurassic granitic rocks are composed of syenogranite,monzogranite,quartz monzonite,granitic porphyry,granodiorite and quartz diorite.The late Jurassic granitic rocks are composed of monzogranite,granitic porphyry,and quartz diorite.The early Cretaceous granitic rocks are composed of monzogranite,quartz syenite,granitic porphyry,and quartz monzodiorite.The samples are characterized by the high SiO;content and total alkalis and are belonged to the high-K calc-alkaline series.And the characteristics of quasi-aluminous to weakly peraluminous（A/CNK<1.1,A/NK>1.0）and the negative relationship between P;O;and SiO;are similar to the characteristics of I-type granite.The samples are enriched in LREE contents and K,Pb and depleted in Nb,Ta,Ti and P.The characteristics of assemblage and geochemical features indicate the Jurassic-Cretaceous granitic rocks formed in the setting of active continental margin related to the subduction.The magmatic zircons of early-middle Jurassic granitic rocks have negativeεHf（t）(-16.60;4.15)and ancient crustal TDM2 values of 1.49 Ga;.28 Ga which indicates the primary magma is from the partial melting of ancient middle-lower crust（Fig.2）.These rocks formed in the setting of active continental margin of subduction of Paleo-Pacific plate.The magma source of granitic rocks is from partial melting of the ancient lower-middle curst caused by the underplating of mantle magma,which formed in the condition of fluid derived from the dehydration of subducted slab affected on the lithosphere mantle.The magmatic zircons of late Jurassic granitic rocks have negativeεHf（t）(-26.24;18.56)and ancient crustal TDM2 values of（2.39 Ga;.87 Ga）which indicates the primary magma is from the partial melting of ancient upper-middle crust（Fig.2）.And these rocks may be formed in the setting of active continental margin of intense subduction of Paleo-Pacific plate.In the intense subduction,the mantle magma is formed in the interaction of fluid derived from the dehydration of subducted slab with the lithosphere mantle,then further underplated the ancient middle-upper crust and make the ancient middle-upper curst partial melting.In this setting,the late Jurassic rocks are distributed widely in eastern North China.The samples in early Cretaceous have a wide range of values of Hf isotope:-24.92;20.88（139 Ma）,-4.72;6.22（130 Ma）,-17.30;11.56（125 Ma;21 Ma）,and the characteristics of Hf isotope indicate the source of earlyCretaceousmagma（middle-uppercrust,middle-lower crust or juvenile crust）is very complicated（Fig.2）.The early Cretaceous granitic rocks were formed in the lithosphere extensional environment when the Paleo-Pacific plate subducted/roll-backed quickly in the direction of NNW with high angle.The regional extension made the asthenosphere upwell and be unstable,and the magma of mantle was formed.Then wide mantle-crust interactions make the crust partial melt,as a result,the source of early Cretaceous igneous rocks which are distributed widely in eastern North China Craton.The participation of depleted mantle components in the process of Late Triassic rock formation in western Liaoning area indicate the time of the lithosphere thinning in the eastern segment of northern margin of NCC begin from the late Triassic（;30 Ma）.The double subduction of Paleo-Asian Ocean and Yangtze Craton in the early period is the reason of the lithosphere thinning.After the double subduction,the mantle-derived magma upwell and underplate the lithosphere mantle and lower crust in a post-collisional extensional tectonic setting.As a result,the lithosphere began to thin but the Craton destruction was not obviously in this period.The participation of depleted mantle components makes the continental crust slightly reforms and grows.The eastern segment of northern margin of NCC was in the setting of active continental margin in Jurassic,and the continuing dehydration and metasomatism of subduction slab changed the physical and chemical properties of the lithosphere mantle.The initial weak subduction in early-middle Jurassic makes the lithosphere become thin but no obvious destruction of Craton.And in this period,the continental crust reformed and grew slightly.As the subduction became stronger during late Jurassic,the thickness of lithosphere in eastern segment of northern margin of NCC become thinner and the destruction of Craton occurred locally and the continental crust reformed and grew to some extent.In early Cretaceous,the change of direction and angle of subduction of Paleo-Pacific led to the regional extension,which is the reason for massive mantle material upwelling and intense crust-mantle interaction.And the lithosphere thinning and destruction of Craton reached the peak.As a result,the effects of reconstruction and hyperplasia of continental crust are obviously.In our opinions,the underplating mechanism of mantle-derived magma occurred mainly in the initial stage（early Mesozoic）oflithosphere thinning,and the delamination of lithosphere mantle or lower crust coexisted while erosion action of mantle material occurred in the stage（late Mesozoic）of strong lithosphere thinning and destruction of Craton.

Geochemical Exploration for Gold and the Association of As-Cu-Pb-Sn-Zn-Li in the Upper Proterozoic Granitoids of the Wadi Rumman Area, Southwest Jordan

The geochemical studies were conducted in an area covering about 15 km2?of the south side of the Wadi Rumman area, SW Jordan. The study area included a part of a basement of complex exposed rocks in southwestern Jordan. The complexes comprised igneous and metamorphic suites, mostly from the late Proterozoic age. A systematic geochemical sampling was conducted using rock and heavy mineral-panned concentrate of geochemical samples. Fifty rock samples were collected from the granitic rocks, simple pegmatite dyke, quartz veins and alteration zone, which covered the area. Next, 45 heavy mineral-panned concentrate samples were collected from the alluvium in the stream sediment within the catchment area, and the dray was sieved to less than 1 mm grain size. The geochemical samples were analyzed for their trace elements and gold by using Ione Conductive Coupled Plasma Emission Spectroscopy (ICP-AES) and the Atomic Absorption Spectrometer (AAS) at Natural Resources Authority (NRA) Labs. The results of the geochemical analysis indicated the presence of gold and heavy minerals in the study area, a result considered abnormal in the rock samples. A strong positive correlation was recorded of Au with As, Cu and W (r =?0.82, 0.7 and 1.0), as with Mo (r = 0.83), Cu with Pb (r = 0.83), Sn with Mo (r = 0.73), Mo with W (r = 0.97), Zn with W (r = 0.71), and Li with Bi (r = 0.7). These correlations revealed gold associated within the hydrothermal alteration, quartz veins and pegmatite dyke. Abnormal metals such as As and Bi were good path-finders to find Au. The HM samples showed low positive linear correlations among the concentrations of Au with As, Zn and Li, and negative linear correlations of Au with Pb, Sn, Bi and W. The combination of both rock and heavy mineral concentrate samples shows four geochemical anomalous areas of gold and heavy minerals. The geochemical signatures of Au and As in the Wadi Rumman appear to be in the hydrothermal alteration, quartz veins and pegmatite dyke, respectively. Heavy mineral concentration sampling delineated the Au geochemical anomaly in area 1 specificities with the rock geochemical anomaly of area 1.

Source Rocks of the Caledonian-Age Granitoid Rocks in Wanyanshan-Zhuguangshan, Southeast China (Ⅱ)——Topological Analysis in Isotopic Multispace

Topological analysis in Sr-Nd-O-Pb_3 six-dimensional isotopic space suggests that the source rocks of the Caledonian-age granitoid rocks in Wanyangshan-Zhuguangshan, southeast China, comprise three end-member components. Isotopic mixing model discrimination indicates that the granitoid rocks were produced through mixing of the three componentsin varying proportions. Comprehensive study of multiple isotopic systems and geochemistry of the granitoid rocks suggests that the three end-member components were crustal rocks which are continent-derived sediments, geosycline sediments and altered basic volcanic rocks.

SOURCE ROCKS OF THE CALEDONIAN-AGE GRANITOID ROCKS IN WANYANGSHANZHUGUANGSHAN, SOUTHEAST GHINA (Ⅰ)——EVIDENCE FROM Sr-Nd-Pb-O ISOTOPIC CONSTRAINTS

Based on the systematic study by means of Sr-Nd-Pb-O isotopic constraints, the Caledonian-age granitoid rocks from Wanyangshan-Zhuguangshan, southeast China, were derived from the regional unexposed basement rocks of middle Proterozoic in age, belonging to the crust- (S-) type granite. Their source rocks were chemically and isotopically heterogeneous, and probably composed of more than two dominant end-members.

福建地区花岗岩岩体结构面及其对建筑边坡稳定性的影响分析

花岗岩地貌是福建主要的地貌之一。花岗岩类边坡在福建地区的工程活动中十分常见,不同类型的边坡的调查方向、设计重点、支护方式都有不同。了解花岗岩类边坡的类型,其结构面的几何特征、分布规律和力学性质等对于分析该类边坡的稳定性十分重要。列举福建地区常见的花岗岩类边坡类型,分析花岗岩结构面几何特征及力学性质,描述了目前工程中岩质边坡普遍采用的勘察和设计分析方法,并通过工程实例,分析土岩结合边坡中结构面的影响,以供参考。

西天山的增生造山过程

西天山位于中亚造山带的西南缘,经历了复杂的增生造山过程。它也是标志塔里木地块北部被动陆缘与西伯利亚地块南侧宽阔活动陆缘最后拼合的构造带。根据近年来的研究进展,将西天山划分为北天山弧增生体、伊犁地块北缘活动陆缘、伊犁地块、伊犁地块南缘活动陆缘、中天山复合弧地体、西天山(高压)增生楔和塔里木北部被动大陆边缘。同时综述了西天山蛇绿岩、高压变质岩、花岗岩类的年代学新资料,讨论了其增生造山的过程。西天山增生造山与早古生代帖尔斯克依古洋、早古生代晚期—晚古生代南天山洋和晚古生代北天山洋3个代表洋盆的演化相关,增生造山结束的时间可能是早石炭世末。二叠纪时期,西天山至整个中亚地区进入后碰撞演化阶段。现有资料证实西天山为晚古生代增生造山带,并非三叠纪碰撞造山带。

造山带岩浆作用的强度和旋回性：以东昆仑古特提斯花岗岩类岩基为例

大陆造山带的重要特征之一是常常发育强烈的岩浆活动。如何刻画造山带古岩浆作用的强度?岩浆从深部添加到中上地壳的速率有多大?岩浆活动强弱的变化规律如何?这些都是近年来国际上有关岩浆动力学的新的研究主题。位于青藏高原北部的东昆仑造山带岩浆活动强烈,尤其发育与古特提斯构造演化相关的晚二叠世-晚三叠世岩浆活动(年龄主要介于270~200Ma之间)。发育于东昆仑东段的香日德复式花岗岩类岩基,主要由早、中、晚三叠世的石英闪长岩、二长花岗岩和花岗闪长岩等多种岩性单元构成,岩石类型多,时间跨度大(258~218Ma),是造山带岩浆活动的缩影。本文以香日德岩基为例,在深入的野外地质、岩石学和年代学研究基础上,结合各岩性单元的出露面积、U-Pb锆石年龄和假定的岩体厚度,对岩浆的体积添加速率(岩浆通量)进行了估算,发现从早到晚,该岩基的岩浆体积添加速率存在着旋回性的变化特征。其中,早三叠世石英闪长岩的岩浆体积添加速率最低,而晚三叠世花岗闪长岩的岩浆体积添加速率则最高,中三叠世介于其间。以2.5km的岩体厚度计算得到的岩浆体积添加速率分别是,早三叠世峰期的添加速率约33km^3/m.y.,中三叠世峰期添加速率约50km^3/m.y.,而晚三叠世的峰期添加速率达到了99km^3/m.y.。研究表明,从230Ma开始,东昆仑地区晚三叠世时期Hf同位素初始比值显著增大,并出现了大规模的铁多金属成矿作用。因此,晚三叠世时期该区强烈的Fe多金属成矿大爆发是在亏损地幔岩浆底侵影响下,发生大规模的花岗岩类岩浆活动和壳幔岩浆活动的结果。

南天山花岗岩类的年代学、岩石学、地球化学及其构造环境

在南天山褶皱带，分布有大量的花岗岩类岩石。按照由老到新的侵位顺序，岩石类型依次为：闪长岩、似斑状花岗岩、二云母花岗岩和碱长花岗岩。精确的锆石Ｕ－Ｐｂ法研究证明，它们形成于石炭纪末期至早二叠世末期。闪长岩、似斑状花岗岩的岩相学和岩石化学具有Ｉ型花岗岩的特征，而二云母花岗岩充分表现了Ｓ型花岗岩的岩相学和岩石化学特征。与洋中脊花岗岩相比，它们不同程度地富集Ｋ２Ｏ、Ｒｂ、Ｔｈ而贫于Ｔａ、Ｎｂ、Ｚｒ，显示了碰撞造山阶段花岗岩的地球化学特征。碱长花岗岩主要由钾长石、钠长石、石英和富羟铁云母组分的黑云母组成。它们普遍具有高的ＳｉＯ２、Ｎａ２Ｏ＋Ｋ２Ｏ、Ｎｂ、Ｙ、ＲＥＥ（Ｅｕ除外）丰度和Ｆｅ／Ｍｇ比值，以及低的ＣａＯ、ＴｉＯ２、Ｓｒ、Ｂａ、Ｅｕ丰度。从而，系统地显示了Ａ２型花岗岩的普遍特征。证明它们形成于后造山垮塌阶段。各种岩石的εＳｒ（ｔ）界于＋３７．７５和＋２１００．７之间，而εＮｄ（ｔ）界于－４．４２和－６．５１之间，证明它们全部源自于陆壳物质的深熔作用。北天山古洋盆于晚石炭世的闭合导致了南天山碰撞造山作用。而在早二叠世末期，更大范围的大陆伸展作用与南天山的后造山垮塌作用同步。

西秦岭宕昌地区晚三叠世酸性火山岩的锆石U-Pb年代学、地球化学及其地质意义

西秦岭造山带在早中生代发育了以印支早期(245~234Ma)和印支晚期(225~205Ma)两期高钾钙碱性花岗岩占绝对优势,并伴有少量火山岩的强烈岩浆活动。本文报道的西秦岭宕昌火山岩总体上是一套以流纹岩为主,并含粗面岩和英安岩的酸性火山岩组合。流纹岩锆石U-Pb测年结果为229Ma,限定其喷发时代为晚三叠世早期。宕昌火山岩属于过铝质的高钾钙碱性-钾玄岩系列,以富集Rb、Ba、Th、U、K并相对亏损Nb、Ta、Ti、P为特征,(87Sr/86Sr)i=0.7048~0.7068,εNd(t)=-4.3^-4.0,亏损地幔模式年龄(t DM)为1.20~1.24Ga。宕昌火山岩起源于下地壳富钾变基性岩的部分熔融,部分岩浆还可能受到了少量地幔或上地壳物质的混染,源区深度约40km。西秦岭地块存在扬子型的中新元古代基底,但不同地段的基底特征存在较大差异。华北板块与扬子板块在西秦岭地区的初始碰撞可能接近229Ma,宕昌火山岩则形成于以整体挤压为主、局部剪切伸展为辅的地壳逐渐加厚的动力学环境。

新疆拜城县波孜果尔A型花岗岩类矿物学特征及岩浆形成的温度条件

新疆拜城县波孜果尔A型花岗岩类为富含铌、钽、锆等有用元素的含矿岩体。通过偏光显微镜、电子探针（EPMA）化学成分分析、电子探针背散射（BSE）对波孜果尔A型花岗岩类的矿物学特征进行了研究,并对岩浆形成的温度条件与构造背景进行了讨论。结果表明,波孜果尔A型花岗岩类包括霓石钠闪石英碱性长石正长岩、霓石钠闪碱性长石花岗岩、黑云母碱性长石正长岩3种岩石类型。主要造岩矿物包括石英、钠长石、钾长石、霓石、钠铁闪石和铁叶云母。副矿物包括锆石、烧绿石、钍石、萤石、独居石、氟碳铈镧矿、磷钇矿等。岩浆平均温度832~839℃,形成于非造山的板内构造环境,且具高温、无水、低氧逸度的成岩特点。

中国不同岩石类型花岗岩类元素丰度及特征

依据采自全国范围内约750个有代表性的大、中型花岗岩类岩体上的768件组合样的实测分析数据,这里计算并提出了碱长花岗岩、正长花岗岩、二长花岗岩、花岗闪长岩、石英二长岩、石英二长闪长岩等中国不同岩石类型的花岗岩类岩石近七十种化学元素或成份的丰度,探讨了中国不同花岗岩类岩石的岩石化学特征和微量元素丰度的特征。

桂北前寒武纪花岗岩类岩石的地球化学与成因

桂北广泛发育前寒武纪花岗岩类岩石 ,按岩石组合特征可区分为二类 ,一类为花岗闪长质岩石 ,另一类为黑云母花岗质岩石。二类岩石的A/NKC值均在 1 .1 0以上 ,属铝过饱和岩石 ,但花岗闪长质岩石相对贫硅、钾 ,富铁、镁 ,贫铷 ,富锶、钡 ,并具有较高的稀土元素总量和轻重稀土元素比值 ;黑云母花岗质岩石则具更显著的铕负异常。二类岩石εNd(T)值的变化范围与四堡群基底相近 ,但花岗闪长质岩石更接近四堡群基底中的变质镁铁质 -超镁铁质杂岩 ,黑云母花岗质岩石则更靠近四堡群基底中的浅变质沉积岩。对岩石产出动力地质背景的全面分析表明 ,区内二类花岗质岩石是华夏地块与扬子地块碰撞俯冲作用的不同阶段由成熟度不同的四堡群变质基底在不同深度经部分熔融作用的产物。

华南腹地白垩纪A型花岗岩类或碱性侵入岩年代学及其对华南晚中生代构造演化的制约

华南腹地存在多个白垩纪的A型花岗岩类或碱性侵入岩,如安徽花山霓辉石钠闪石花岗岩、福建大沅村霓辉石钠铁闪石花岗岩、广东恶鸡脑霞石方钠石正长岩以及浙江大和山辉石石英正长斑岩、苏村晶洞钾长花岗岩。锆石SHRIMP和矿物的40Ar-39Ar年代学研究表明,这些岩石主要形成于137-86Ma。以本文的年代学研究为基础,并结合前人大量研究成果, 将华南晚中生代的A型花岗岩类或碱性侵入岩大致分成三期:(1)侏罗纪(184-152Ma)A型花岗岩类或碱性侵入岩,主要沿“十-杭裂谷带”南段分布,在赣南也有分布,可能与古太平洋板块低速斜向俯冲或平移所导致的走滑伸展或与不受古太平洋板块运动影响的岩石圈伸展有关;(2)早白垩世(139-123Ma)A型花岗岩类或碱性侵入岩,分布于政和-大埔断裂带以西,可能与古太平洋板块快速斜向俯冲所导致的弧后伸展或岩石圈减薄有关;(3)晚白垩世(101-86Ma)A型花岗岩类或碱性侵入岩,主要沿闽浙沿海地区分布,同时在华南腹地也有零星分布,可能与大陆边缘弧的塌陷(collapse)或俯冲洋壳反转(roll- back)后的岩石圈伸展有关。