赣北彭山还原性S型花岗岩成因及其对Sn富集的启示:来自锆石微量元素的证据

彭山锡多金属矿集区成矿区划位于长江中下游成矿带与江南钨多金属成矿带的过渡部位。以前研究认为与锡大规模成矿有关的花岗岩通常为高分异的过铝质岩浆,但是关于Sn在还原性岩浆中与矿物相的分配和迁移的氧逸度阈值犹未可知,锡与钨在赣北地区成矿的分带分区(解耦)究竟是受岩浆源区特征的控制还是为氧逸度所制约,目前尚不清楚。本文对区内花岗岩岩石成因、锡的来源、岩浆演化早期的氧化还原条件,及其对锡在岩浆中的分配、萃取和迁移的控制过程开展了研究,即对彭山岩体进行了精细的锆石原位微区分析测试。结果显示,锆石P含量普遍较高,结合P(∑REE+Y)拟合的3条趋势线的斜率分别为0.91、0.85和0.81,与S型花岗岩(∑REE+Y)<1.15×P演变规律相符。在Eu/Eu^(*)Yb N/Gd N关系图解中未显示出与Ti分离曲线的同步协变关系,相反,各组岩石均显示为负相关关系,说明3组锆石Eu/Eu^(*)的比值受榍石与斜长石的共结晶的影响较为有限。依据Hf Ce^(4+)/Ce^(3+)zircon和Ti Ce^(4+)/Ce^(3+)zircon关系图,白云母花岗岩数据区域均位于趋势线末端,与黑云母二长花岗岩和花岗斑岩相比,显示出更低的氧逸度特点。Eu/Eu^(*)与Ce^(4+)/Ce^(3+)zircon比值在各岩石单元中所表现出的还原程度是相耦合的,即组成彭山岩体的3个岩石单元——成矿后花岗斑岩岩脉、黑云母二长花岗岩岩基和白云母花岗岩成矿岩株,其锆石Eu异常(Eu/Eu^(*))和Ce^(4+)与Ce^(3+)比值(Ce^(4+)/Ce^(3+)zircon)呈逐渐递减趋势。双桥山群中1.5~1.3 Ga砂泥质沉积岩与细碧角斑岩系组成的海相古火山喷发沉积建造,可能提供了本区Sn的初始来源。白云母花岗岩成矿岩株的氧逸度显著低于大湖塘石门寺矿床的花岗岩,锆石微量元素揭示了富锡岩浆演化比富钨岩浆具有更低的氧逸度。

北山造山带东部微波山早志留世S型花岗岩成因及构造背景

为研究北山造山带东部微波山地区的大地构造背景,选取在该地区广泛发育的花岗岩为研究对象,通过野外地质工作、锆石U-Pb年代学、岩石学及地球化学等研究方法,深入剖析了微波山花岗岩的形成时代、类型、成因及构造背景。锆石年龄为(440.80±0.19)Ma和(155.05±0.37)Ma,表明该岩体形成于早志留世,并在侏罗世形成复式岩体。岩石学特征定名本次样品为二长花岗岩,地球化学特征显示成因类型为S型花岗岩,稀土配分曲线与微量元素蛛网图为右倾型,显示岛弧岩浆岩特征。根据Yb、Y、Sr、Al_(2)O_(3)的含量特征确定其中两个样品为埃达克岩,建立微波山构造-岩浆演化模型,早志留世小黄山洋盆向北俯冲,幔源岩浆底侵,长英质岩浆移出形成岛弧岩浆岩。

Geochemical Characteristics and Tectonic Significance of Triassic Granite from Taer Region, the Northern Margin of West Kunlun

Late Hercynian-early Indosinian （Triassic） granite is widely distributed around the Taer region of the northern margin of West Kunlun. The rock mass is mainly composed of calc-alkaline porphyroid biotite adamellite and characterized by SiO2-rich, high-Ca, moderate-alkaline, and strongly peraluminous attributes, and relatively low ~REE with LREE enrichment and a moderate Eu anomaly. As shown in the trace element spider web diagram, distinct peaks appear for Th, La, Nd, and Zr and clearly low values appear for Ba, Nb, Sr, P, and Ti. Further, compared with the primitive mantle, Rb/Sr and Rb/Ba are considerably higher and Nd/Th and Nb/Ta are relative low, all falling into the scope of the crust-origin rocks, indicating the characteristics of the crust-origin S-type granite. The rock mass＇s zircon U-Pb isotopic age is determined to be 235.7 -~ 3.9 Ma. On the basis of the age data, spatio-temporal location, lithology, and geochemistry of the rock mass, we conclude that the formation of the rock mass is closely related to the strong compressional orogenic movement （240 Ma） of the Tianshuihai terrane and the South Kunlun terrane. The rock mass is the product of the collision orogenic movement. However, distinct differences are observed between the studied rock mass and the synorogenic Bulunkou rock mass, which may be caused by the different collision strength and different positions with respect to the collision zone.

Two Types of Granites in the Western Yangtze Block and Their Implications for Regional Tectonic Evolution： Constraints from Geochemistry and Isotopic Data

In the western Yangtze Block, widespread Mesoproterozoic to Neoproterozoic rocks are the key to understanding the Precambrian tectonic-magmatic evolution of the region. However, their petrogenesis and tectonic setting are still controversial. In this paper, zircon U-Pb ages, Sm-Nd isotopic and whole-rock geochemical data are reported from selected fresh samples in the southern Dechang county, southwestern China, in order to constrain their emplacement age and magma source, as well as their petrogenesis and tectonic setting. They are mainly composed of biotite monzogranite, monzonitic granite, biotite granodiorites, and quartz diorite. Two ages of 1055 ± 43 Ma and 837.6 ± 3.8 Ma were obtained through zircon U-Pb dating by LA-ICP-MS and LA-MC-ICP-MS, respectively. According to their major element compositions, the Grenville-age granites are peraluminous calc-alkaline series calcic S-type granite. In contrast, the mid-Neoproterozoic granites are metaluminous calc-aikaline series alkalic I-type granite. Furthermore, the S-type granites are enriched in LREEs relative to HREEs with （La/Yb）N ratios of 3.85-18.56 and underwent major fractionation with strongly negative Eu anomalies （Eu/Eu＊ = 0.38-0.66）. In the MORB-normalized trace element variation diagram, all the samples are enriched in Ce and large ion lithophile elements such as Rb, Th, and K, and depleted in high field strength elements such as Nb, and Ti, with negative Sr and Ti anomalies. The I-type granites are enriched in LREEs with slight negative Eu anomalies （Eu/Eu＊= 0.83-0.93）. They are characterized by the enrichment of highly incompatible elements （such as K, Rb, Ba, Th） and LREEs, relative to MORB. Neodymium isotopic data show that the S-type granites display 143Nd/144Nd values of 0.51241-0.51256, and have eNa （t = 1055 Ma） values of （-3.29） to （-3.81）. Calculated tDM ages yield values from 1.87 to 1.91 Ga with the tDM.2stg ages of 1.86 to 1.9 Ga. The I-type granites have 143Nd/144Nd ratios between 0.51192 and 0.51195, corresponding to initial eNd （t = 837 Ma） values of 1.22 to 5.63. Calculated tDM ages yield values from 1.0 to 1.38 Ga and the tDM.2stg ages yield values from 0.99 to 1.06 Ga. The S-type granites are distinguished as syn-collision granite, whereas the I-type granites were formed as arc magmas according to the Rb-（Yb＋Ta） and R1-R2 tectonic discrimination diagrams. To conclude, there are two types of spatially associated granite, the Mesoproterozoic S-type granite which were derived from re- melting of upper crustal mudstone and/or clastics and resulted from the convergence of two continental plates, and the mid-Neoproterozoic I-type granite which formed in continental arc and resulted from mantle-derived magma mixed crust material, in the western Yangtze Block. Furthermore, we suggest that collision between the Yangtze and Cathaysia blocks occurred at about 1055 Ma, and caused the S- type granite. The I-type granite related to the subduction of oceanic lithosphere eastward underneath the Yangtze Block in the mid-Neoproterozoic.

Determination of the Neoproterozoic Shicaogou Syn-collisional Granite in the Eastern Qinling Mountains and Its Geological Implications

The Shicaogou granite has been identified as a magnesian (Fe-number=0.71-0.76), calcic to calc-alkalic (MALI=3.84-5.76) and peraluminous (ASI=1.06-1.13) granite of the syn-collisional S-type, with high SiO2(>71%), A12O3 (>13%) and Na2O+K2O (6.28%-7.33%, equal for NaO2 and K2O). Trace element and REE analyses show that the granite is rich in LILE such as of Rb, Sr, Ba and Th, and poor in HFSE like Yb, Y, Zr and Hf. Its Rb/Sr ratio is greater than 1; the contents of Nb and Ta, and the ratio of Nb/Ta as well as the REE geochemical features (e.g. REE abundance, visible fractionation of LREE and HREE and medium to pronounced negative Eu anomalies) are all similar to those of crust-origin, continent-continent syn-collisional granite. Moreover, the granite exhibits almost the same pattern as that of the typical continent-continent syn-collisional granite on the spider diagram and all samples fall within the syn-collisional granite field.The cathodoluminescence (CL) investigations have revealed that the zircon from the Shicaogou granite represents a typical magmatic product characterized by its colorless, transparent and euhedral crystals, and distinct zoning of oscillatory bands. Residual cores of irregular zircon can be found in a few enhedral grains. Trace element studies of the zircon grains, with high contents of P, Y, Hf, Th, U and REE and high ratios of Th/U, obviously positive Ce anomalies and HREE enrichment compared to LREE, also result in the same conclusion.The LA-ICP-MS U-Pb isotopic data from 24 spots of 21 zircon grains demonstrate that 20 spots in the oscillatory zone yield an average weighted 206Pb/238U age of 925±11 Ma, indicating that the Shicaogou granite was formed in the Neoproterozoic. Combined with other Neoproterozoic syn-collisional granites found in the study area, the present geochronological determination can further reveal that collision-amalgamation events could have occurred among some continental blocks in the Qinling orogenic belt during the Neoproterozoic. This in turn provides an accurate chronological constraint on the Neoproterozoic break-up and convergence in the belt.

高铁镁S型花岗岩成因剖析——以华南早古生代金溪花岗岩为例

S型花岗岩是大陆上地壳分布最广泛的火成岩,般被认为起源于古老变质沉积岩的部分熔融。近年来,越来越多的研究指出世界上有些S型花岗岩,比如南非Cape花岗岩岩基、美国Cardigan岩体以及中国九岭岩体等.

Tantalite in Suzhou Granite: Mineralogy and Geological Implications

Tantalite, occurring as intergranular tabular crystals, was reported for the first time in the Suzhou granite. Electron microprobe analyses show that it is rich in W and Ti, with a Ta/(Ta + Nb) ratio ranging from 0. 5 to 0. 73 and a Mn/ (Mn + Fe) ratio between 0. 20 and 0. 40. It is structurally distinct from isomorphic tapiolite by a remarked Ag Raman peak at 880cm -1. The associated zircon is striking by significant enrichment of Hf, with the HfO2 content amounting up to 35%-40%. The discovery of tantalite suggests that the Suzhou granite should be classified as a S-type granite instead of Amtype as considered previously.

Early Paleozoic Granite in the Talate Mining District, Chinese Altay, and its Geological Significance for the Altay Orogenic Belt

Zircon dating,geochemical and Nd-Sr isotopic analyses have been determined for samples from two granitic intrusions in the Talate mining district,Chinese Altay.Our data suggest that these intrusions were emplaced from 462.5 Ma to 457.8 Ma.These rocks have strong affinity to peralumious S-type granite and are characterized by prominent negative Eu anomalies(δEu=0.20–0.35),strong depletion in Ba,Sr,P,Ti,Nb,Ta and positive anomalies in Rb,Th,U,K,La,Nd,Zr,Hf.Nd-Sr isotopic compositions of the whole rock show negativeεNd(t)values(-1.21 to-0.08)and Mesoproterozoic Nd model ages(T2 DM=1.20–1.30 Ga).Their precursor magmas were likely derived from the partial dehydration melting of Mesoproterozoic mica-rich pelitic sources and mixed with minor mantle-derived components,under relatively low P(≤1 kbar)and high T(746–796℃)conditions.A ridge subduction model may account for the early Paleozoic geodynamic process with mantle-derived magmas caused by Ordovician ridge subduction and the opening of a slab window underplated and/or intraplated in the middle–upper crust,which triggered extensive partial melting of the shallow crust to generate diverse igneous rocks,and provided the heat for the crustal melting and juvenile materials for crustal growth.

黑龙江省团结沟浅成低温热液金矿床成因——锆石U-Pb定年、元素地球化学和Hf-S-Pb-He同位素证据

团结沟金矿床位于黑龙江省中部嘉荫县境内,是我国东北地区最大的浅成低温热液型金矿床。本文对与成矿有关的花岗闪长斑岩和花岗斑岩进行了系统的岩相学、锆石U-Pb定年、全岩主量和微量元素、LA-ICP-MS锆石原位微量元素、Hf同位素、LA-ICP-MS原位S同位素及矿石的载金矿物黄铁矿Pb-He同位素研究。结果表明:花岗闪长斑岩和花岗斑岩的锆石U-Pb年龄分别为(105.9±1.1)和(102.3±1.2)Ma,属于钙碱性-高钾钙碱性系列岩石;两者呈现富集轻稀土元素和Rb、K等大离子亲石元素,亏损P、Ti、Nb、Ta等高场强元素特征;花岗闪长斑岩中锆石Ce^(4+)/Ce^(3+)值为165~656(均值为322)、Ti饱和温度为605~715℃(均值为658℃),花岗斑岩中锆石Ce^(4+)/Ce^(3+)值为359~868(均值为480)、Ti饱和温度为606~680℃(均值为646℃);两者的锆石ε_(Hf)(t)值分别为6.9~8.1和5.6~8.2;黄铁矿的δ^(34)S值为-7.8‰~-0.2‰,均值为-3.5‰,普通铅同位素比值^(206)Pb/^(204)Pb值为18.160~18.399、^(207)Pb/^(204)Pb值为15.538~15.590、^(208)Pb/^(204)Pb值为38.135~38.340;黄铁矿中流体包裹体R/R_(a)值为0.75~1.23。综合研究表明:与成矿密切相关的岩浆为同源结晶岩浆演化产物,岩浆就位发生在早白垩世,初始岩浆可能来源于古太平洋板片俯冲背景下年轻下地壳物质部分熔融的产物,形成过程中混合部分幔源物质;成矿流体来自深源岩浆,具有壳-幔混源特征(地壳为主,地幔流体占8.23%~13.62%),花岗斑岩更高的氧逸度和更低的岩浆结晶温度为金富集过程和良好的运移提供了基础,有利于大规模金矿化。

粤北地区塘洞岩体地球化学特征及地质意义

塘洞岩体位于粤北地区长江铀矿集区北部,具有较好的铀成矿地质条件。文章通过对塘洞岩体岩相学、地球化学分析,初步探讨了塘洞岩体成因及其形成的构造环境。结果表明:塘洞岩体岩性为中粒二云母花岗岩,具有高硅(SiO_(2)=72.77%~73.83%)、富铝(Al_(2)O_(3)=13.13%~13.82%)、富碱(K2O=5.00%~6.84%,Na_(2)O=1.55%~2.67%),且钾大于钠,贫铁、镁、钙、钛、磷,铝饱和指数(A/CNK=1.08~1.28)大部分大于1.1的特征,属高钾钙碱性弱过铝质-过铝质花岗岩;稀土元素总量较高,属轻稀土富集型(LREE/HREE=8.45~12.86),明显铕负异常(δEu=0.24~0.30);富集大离子亲石元素Rb、Th、U、K、Pb,而贫Nb、Ta、Ti、Zr等高场强元素。塘洞岩体CaO/Na_(2)O=0.16~0.58、Rb/Sr=5.01~8.19、Ra/Ba=0.90~1.94,指示其源区为砂质岩与泥质岩混合,属于S型花岗岩,主要为同碰撞后期在碰撞加厚向伸展减薄构造转换阶段的地壳物质经部分熔融形成的。

北山花岗岩S型/I型空间变化规律及含矿性

北山地区花岗岩十分发育,出露面积接近总面积的30%,形成时代以华力西期为主,约占80%以上。笔者根据岩石化学判别统计,本区花岗岩的S型/I型个数比例,北带0.33,中带0.54,南带0.59,说明从北向南,I型花岗岩逐渐减少,S型花岗岩逐渐增多。区内花岗岩类为重要的含矿岩石,其中典型斑岩铜矿床与I型花岗质斑岩有关,当出现铜铅组合时则与S型花岗质斑岩有关;钼矿床有关花岗岩一般属I型,当出现钨钼组合时则向S型花岗岩过渡;钨锡矿床主要与S型花岗岩有关;金矿床有关的花岗岩既有I型,也有S型,专属性不明显。

桂东南大容山-十万大山S型花岗岩带的成因:地球化学及Sr-Nd-Hf同位素制约

本文报道桂东南大容山-十万大山花岗岩带浦北岩体(东北带)、旧州岩体(中部带)和台马岩体(西南带)全岩的主、微量元素、Sr-Nd同位素和锆石的LAM-MC-ICPMS原位Hf同位素分析结果。岩石学及元素地球化学结果显示:上述三个岩体为典型S型花岗岩;高I_(Sr)(>0.721)和低ε_(Nd)(t)(-13.0～-9.9)意味着它们可能来自古老地壳的重熔。岩浆结晶(～230Ma)锆石的ε_(Hf)(t)值主要集中在-11～-9,相应的T_(DM2)模式年龄为1.9～1.8Ga;少数结晶锆石的ε_(Hf)(t)值逐渐升高到-4.5,T_(DM2)降低为～1.5Ga。捕获锆石(1681～384Ma)的的ε_(Hf)(t)值分布在-17.1～+3.4,T_(DM2)主要集中在2.4Ga、1.9Ga和1.5Ga。大部分岩浆结晶锆石ε_(Hf)(t)值与根据"全岩ε_(Nd)(t)值和‘地壳Hf-Nd相关’预测值"基本一致,表明平均地壳存留年龄为1.9Ga的地壳是最重要的物源区。部分岩浆锆石与捕获锆石具有相同的T_(DM2)～1.5Ga,表明平均地壳存留年龄为1.5Ga的物源区参与了该花岗岩带的形成;由于缺少T_(DM2)>2.0Ga的岩浆锆石,少量平均地壳存留年龄为2.4Ga的再循环地壳物质参与了该花岗岩带的形成。因为缺少显著幔源特征的高ε_(Hf)(t)值锆石,本文认为地幔物质基本没有参与该S型花岗岩带的形成。

原特提斯洋在滇西南地区的俯冲记录:来自保山地块奥陶纪花岗岩的年代学、地球化学以及Hf-Nd同位素的支持

中国西南地区在早古生代期间位于冈瓦纳大陆北缘,该地区保存有早古生代岩浆岩记录,它们的形成与原特提斯洋的演化密切相关。本文报道了滇西南地区保山地块平达乡附近的早古生代花岗岩的岩石学、全岩主-微量地球化学、LA-ICP-MS锆石U-Pb年龄、锆石Hf同位素和磷灰石Nd同位素组成,以探讨保山地块早古生代花岗岩的岩石成因、岩浆源区性质以及岩体形成的地球动力学机制。通过对保山地块平达花岗岩中岩浆锆石开展LA-ICP-MS U-Pb同位素测试,结果显示花岗岩形成于465.9~454.9Ma,是中-晚奥陶世岩浆作用的产物。平达岩体主体岩性为二长花岗岩,主要矿物组成为斜长石、石英和碱性长石(条纹长石和正长石),次要矿物为黑云母和白云母。本文报道的花岗岩样品显示出高的SiO_(2)(72.16%~76.87%)和Al_(2)O_(3)(12.50%~14.36%)含量,低的MgO(0.12%~0.64%)、Mg#(20.9~35.9)、Cr和Ni含量以及较高的Rb/Sr和Rb/Ba比值;结合花岗岩较高的A/CNK值(1.06~1.45),显示弱过铝质至强过铝质的特征,表明其属于S型花岗岩。此外,平达岩体二长花岗岩样品具有低的Al_(2)O_(3)/TiO_(2)比值和变化的CaO/Na_(2)O、Rb/Sr、Rb/Ba比值,表明其岩浆源区包含泥质岩石和砂质岩石,显示混合源区的特征。结合滇西南早古生代二长花岗岩变化较大的锆石εHf(t)值(-11.10~-4.05)、磷灰石εNd(t)值(-8.76~-6.96)和Hf同位素二阶段模式年龄(2140~1704Ma),表明它们的岩浆源区为古元古代地壳中泥质岩石和砂质岩石混合源区。综合滇西南地区广泛发育的早古生代岩浆岩以及同时期的蛇绿混杂岩记录,本文认为保山地块早古生代S型花岗岩是地壳沉积组分部分熔融的产物,形成于原特提斯洋西向俯冲相关的活动大陆边缘背景。

离子吸附型轻稀土和重稀土矿床成矿母岩地球化学特征对比研究:以关西和大埠花岗岩体为例

离子吸附型稀土矿床是花岗质岩石为主的成矿母岩经历后期风化淋积作用而形成,是世界上重要的稀土资源之一,因此其矿床成因备受关注。目前不同类型离子吸附型稀土矿床的成矿母岩的性质还没有得到很好限制,这也制约对该类型矿床成矿理论的完善。本次以关西离子吸附型轻稀土矿床(母岩为碱性长石花岗岩)和大埠离子吸附型重稀土矿床(母岩为白云母花岗岩)的成矿母岩为研究对象,对它们进行系统的年代学和地球化学分析,并结合前人研究成果进行对比,揭示离子吸附型轻稀土和重稀土矿床在成矿母岩的系统性差异。结果显示,关西碱性长石花岗岩(190 Ma)和大埠白云母花岗岩(155 Ma)均形成于燕山期,且具有较高的铝饱和指数,A/CNK均为1.07~1.38,指示二者均属于过铝质岩石,为地壳沉积物熔融的产物。关西碱性长石花岗岩高场强元素(Zr、Nb、Ce)含量高、Ga/Al(3.33~4.33)值和锆饱和温度(895~922℃)较高,表明其为铝质A型花岗岩。而大埠白云母花岗岩具有较低的锆饱和温度(762~795℃),含石榴子石和白云母等铝饱和矿物,应属于S型花岗岩;且大埠白云母花岗岩具有较低Nb/Ta(2.55~5.10)和Zr/Hf(12.2~20.7)值,并含有萤石等富F矿物,显示出高演化花岗岩的特征。通过系统的统计对比发现,A型花岗岩形成的温度更高,有利于源区富稀土矿物的熔融,并抑制了岩浆上升过程中稀土矿物的分离结晶,最终促进了稀土元素在岩体中聚集,从而有利于形成离子吸附型轻稀土矿床;而部分高演化的S型花岗岩中,由于出现石榴子石等富重稀土的矿物,从而富集重稀土,而且其普遍富F的特征也有利于岩浆经历更为充分的演化,促进重稀土元素在岩石中的富集,有利于形成离子吸附型重稀土矿床。

藏北羌塘南缘早白垩世青草山强过铝质S型花岗岩的成因:来自地球化学和锆石U-Pb年代学的约束

藏北羌塘南缘扎普-多不杂岩浆弧内的青草山花岗岩体由花岗斑岩和石英二长斑岩组成,目前缺乏地球化学和年代学数据来约束其成因和形成时代。用LA-ICP-MS方法测得石英二长斑岩锆石206Pb/238U年龄加权平均值为122±1 Ma（MSWD=3.9）,花岗斑岩的锆石SHRIMP U-Pb年龄为114.6±1.2 Ma（MSWD=1.1）,表明岩体形成于早白垩世。岩体含白云母、堇青石,无角闪石,具有富铝（A12O3含量：14.81%~15.86%）、贫钙（CaO含量：1.10%~2.44%）、总碱含量高（K_2O＋Na_2O含量：6.86%~8.80%）的特征,铝饱和指数A/CNK为1.06~1.20,在CIPW标准矿物计算中出现刚玉分子（1.20%~2.86%）,未出现透辉石,表明该岩体为一套强过铝质亚碱性S型花岗岩。（La/Yb）N=3.24~16.20,LREE/HREE=4.37~12.4,在配分曲线上显示左高右低的特征,富集Rb,Th,U,K,La,Ce等大离子亲石元素,亏损Ta,Nb,P,Ti,Y等高场强元素,具有较典型的岛弧岩浆岩地球化学特征。研究结果揭示,青草山花岗岩为班公湖-怒江洋壳北向俯冲背景下,上地壳杂砂岩质成分发生部分熔融作用的产物。

大别北麓汤家坪花岗斑岩锆石LA-ICPMS U-Pb定年和岩石地球化学特征及其对岩石成因的制约

河南商城县汤家坪花岗斑岩产于大别造山带北麓,岩体位于早白垩世达权店花岗岩体的南缘。岩体斑晶含量占10%左右,主要由钾长石、斜长石和石英组成,基质主要由钾长石、斜长石、石英和少量黑云母组成,副矿物主要为磁铁矿、赤铁矿、锆石。花岗斑岩中锆石U-Pb年龄为121.6±4.6Ma,为早白垩世中晚期。汤家坪花岗斑岩含白云母,无角闪石,具高硅(SiO2>72%)、高碱(Na2O+K2O>7.4%)的特征,铝饱和指数(ACNK)为0.99～1.18,轻稀土富集、重稀土亏损(La/Yb)N=10.9～44.5,明显亏损Eu(δEu=0.40～0.58)、Sr、Ba、Nb等。P2O5与SiO2含量呈正相关关系、Pb与SiO2含量呈负相关关系、Y、Th随Rb升高而降低,属弱过铝质高分异S型花岗岩。汤家坪花岗斑岩εHf(t)(-17.6～-10.4)和εNd(t)(-15.5～-13.7)值均显示出壳源特征,tDM2(Hf)和tDM2(Nd)分别为1843～2281Ma和2034～2178Ma,反映汤家坪花岗斑岩来源于古老地壳物质的重熔,中等的初始Sr同位素指示源岩中可能有部分低成熟度地壳物质加入。结合稀土元素特征,认为汤家坪花岗斑岩源岩来源较深,主要源于下地壳物质。

黑龙江东南部穆棱地区“麻山群”的特征及花岗岩锆石SHRIMPU-Pb定年--对佳木斯地块最南缘地壳演化的制约

通过对佳木斯地块南缘穆棱地区常兴村-新兴村剖面的研究,认为这里是"麻山群"和"黑龙江群"的结合部位,具有古大陆边缘的性质。穆棱地区的"麻山群"为佳木斯地块南缘的陆壳基底,其南侧的"黑龙江群"为包括洋壳残片在内的增生-碰撞杂岩。对"麻山群"混合岩的SHRIMP锆石U-Pb定年结果表明:佳木斯地块存在中—新元古代的结晶基底,并遭受到约500Ma变质作用的影响。侵入"麻山群"杂岩的花岗岩的岩石学、地球化学研究表明,这些花岗岩具有S型花岗岩的特征;其SHRIMP锆石U-Pb分析表明,其形成年龄为486Ma±3Ma,略晚于前人确定的"麻山群"杂岩约500Ma的麻粒岩相变质作用,为同碰撞或碰撞后花岗岩。这些资料进一步证明,该地区可能经历了晚泛非—早加里东期的碰撞造山作用。

华北克拉通北缘隆化地区S型花岗岩的独居石年龄图谱

位于华北克拉通北缘中段的隆化S型花岗岩由石榴石黑云母花岗岩、石榴石花岗岩以及片麻理化的黑云母花岗岩组成。其主体岩性石榴石黑云母花岗岩Si02和A1203含量分别为64．09％～69．6％以及14．6％～16．13％，K20／Na：O〉1．0。A／CNK〉1．0，Mg。在20．76～34．89之间变化，具有明显的Nb、Ta、P、Ti和Sr亏损以及Rb、K和Th富集。石榴石黑云母花岗岩（样品JB6031．1）采用独居石电子探针U-Th-Pb化学法进行测年，获得了2553±120Ma、2180±42Ma和1854±24Ma三个年龄峰值。一颗独居石内部成分分带上6个分析点定年结果构成2553±120Ma的峰值年龄，这一年龄与我们最新获得的2506±7Ma和2541±8Ma（继承锆石年龄）LA-ICP-MS锆石U-Pb同位素年龄相似，我们将这一独居石年龄解释为继承独居石的年龄，表明在赤城．隆化断裂以北存在太古宙陆块，并且在后期构造-热事件中发生部分熔融形成S型花岗岩。该独居石颗粒幔部成分分带上10个分析点的测年结果揭示的峰值年龄为2181±42Ma，该年龄也是出现频率最高的年龄值，我们建议2181±42Ma为S型花岗岩的结晶年龄，反映了S型花岗岩的侵位时代。独居石颗粒外部成分分带上8个分析点的测年结果构成1854±24Ma的峰值年龄，该年龄与华北克拉通中部带的变质年龄接近，我们将其解释为s型花岗岩的变质年龄，表明华北克拉通北缘的构造演化与中部带的构造演化密切相关。

贺兰山北段古元古代S型花岗岩岩石地球化学、锆石U-Pb年代学及其地质意义

对贺兰山北段似斑状花岗岩进行岩相学、岩石地球化学及锆石U-Pb年代学进行研究,探讨其成因机制及其源岩性质。研究结果表明：似斑状花岗岩具有高物质的量比即n（Al2O3）/n（Na2O＋K2O）（记为A/CNK,为1.18-1.29）、低FeOt和MgO质量分数比即w（FeOt）/w（MgO）（小于10）、低P2O5（质量分数为0.15%-0.22%）和高K2O（质量分数为5.09%-5.86%）的地球化学特征,属于典型的强过铝质S型花岗岩。岩石轻稀土富集,轻重稀土分异明显（[w（La）/w（Yb）]N=10.4-153.6）,具有明显的Eu负异常（δ（Eu）=0.19-0.49）;同时,岩体富集大离子亲石元素（LILE）K和Rb,亏损高场强元素（HFSE）Nb,Ta,Zr,Hf和Ti等。似斑状花岗岩与孔兹岩具有相似的微量和稀土元素地球化学特征,推断其应为孔兹岩部分熔融的产物。较低的w（CaO）/w（Na2O）、较高的w（Rb）/w（Sr）和w（Rb）/w（Ba）暗示孔兹岩的原岩应为泥质岩或是以泥质岩为主的、成熟度较高的沉积岩,反映其当时的沉积环境应为被动大陆边缘,而非活动大陆边缘。似斑状花岗岩LA-ICP-MS锆石U-Pb年龄为（1922±31）Ma,与孔兹岩带内所记录的1.92-1.90Ga期间的岩浆-变质事件相吻合,可能反映了构造体制由碰撞挤压到伸展的转变。

华北板块北缘中段新太古代的陆-陆碰撞事件:来自合教S型花岗岩的证据

通过对内蒙古达茂旗合教地区具有明显构造意义的新太古代S型花岗岩的主量元素、微量元素及SHRIMP锆石U-Pb年代学的研究,为揭示华北板块北缘新太古代末的构造环境提供了进一步的证据。合教花岗岩的主量元素特征表明它是高分异的强过铝S型花岗岩;其里特曼指数σ为0.54～0.57,属于低钾钙碱性岩石。稀土元素总量为243.8～427.1μg/g。球粒陨石标准化分配模式显示LREE相对富集,HREE相对亏损;(La/Yb)N为14.88～18.18,Eu具有较大的负异常(Eu*/Eu=0.31～0.65);模式图总体呈一右倾的海鸥型。微量元素显示Nb,Ta,Zr,Hf,Ti等高场强元素相对亏损。合教花岗岩的微量元素组成表明其来源于正常厚度的大陆地壳,形成于低压高温的后碰撞环境,相当于澳大利亚拉克伦造山带的S型花岗岩。合教花岗岩的SHRIMP锆石U-Pb年龄为2556±8Ma,属于新太古代晚期。合教强过铝S型花岗岩反映在新太古代晚期华北板块北缘中段可能发生了一次陆-陆碰撞事件,也表明固阳地区同时期的赞岐岩可能形成于后碰撞环境而非板片消减带。