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1.
西大别红安地区榴辉岩样品的锆石CL图像显示这些锆石为经历了后期变质重结晶改造的岩浆锆石;挑选锆石内部无变质重结晶区域进行微量元素测试,结果表明其具有典型的岩浆锆石微量元素特点;LA—ICPMS锆石U—Pb年龄测定为1068Ma±23Ma(MSWD=1.8),应为该榴辉岩原岩形成年龄,指示该地区在中元古代晚期有岩浆活动发生;而锆石的εHf(t)值为8.2~18.1(加权平均结果为14.06±0.62),TDM为892Ma~1300Ma(加权平均结果为1062Ma±21Ma),表明榴辉岩的原岩来自亏损地慢。这些结果证实,大别地区存在中元古代晚期到新元古代早期的岩浆作用,且这一时期扬子板块有不同程度的地壳生长。  相似文献   

2.
福建漳州角美花岗岩与闪长质包体的岩石成因及意义   总被引:3,自引:2,他引:1  
本文选择福建沿海漳州地区的角美花岗岩和包体进行了锆石U-Pb年代学和Hf同位素地球化学研究。结果表明,黑云母花岗闪长岩(106.4±1.8Ma)和岩体中的闪长质包体(105.6±1.0Ma 和106.5±1.0Ma)具有相同的锆石U-Pb年龄,为同期岩浆作用的产物,它们都是高钾钙碱性系列偏铝质岩石。花岗闪长岩具有相对较为均一的锆石Hf同位素组成(εHf(t)=2.2~3.7),表明其为新生地壳部分熔融的产物。闪长质包体具有更亏损的锆石Hf组成(εHf(t)=0.9~5.5)。地球化学数据结合野外证据表明岩体形成过程中经历了岩浆混合作用。福建沿海地区96~106Ma岩浆作用的发育处于古太平洋板片俯冲造成的伸展背景。  相似文献   

3.
本文报道了徐淮地区5个早白垩世adakitic岩体全岩的Pb同位素组成和其中3个岩体的锆石IA—ICP—MSU-Pb定年结果,并讨论了岩浆源区的性质和华北克拉通东部中生代早期的构造演化。结果表明,班井、丰山和蔡山岩体形成于早白垩世,其^206Pb/^238U加权平均年龄分别为127±1Ma、129±2Ma和131±1Ma。利国、班井、夹沟、丰山和蔡山岩体的全岩(^206Pb/^204Pb)。(^207Pb/^204Pb),和(^208Pb/^204Pb)。初始比值分别变化于17.957~18.620、15.508~15.655和38.129~38.710之间。综合早白垩世adakitic岩石高的放射成因Pb同位素组成以及继承锆石年代学和其中榴辉岩类捕虏体锆石U-Pb年代学和地球化学的研究成果,可以认为华北克拉通东部徐淮地区早白垩世adakitic岩石的岩浆源区以断离的扬子克拉通俯冲板片(基底物质)为主,并有拆沉的华北克拉通基底物质的参与。这与扬子克拉通沿北西方向俯冲于华北克拉通之下的构造模式相吻合。  相似文献   

4.
为了弄清楚勉略构造带中三岔子岛弧火山岩的形成时代及源区特征,对南秦岭勉略缝合带三岔子岛弧蛇绿混杂岩中的辉绿岩墙样品进行了锆石U—PB年代学、锆石Hf同位素组成及微量元素组成研究。结果表明,三岔子辉绿岩中的锆石主要包括2个年龄区间:有8颗锆石记录古生代年龄信息,其n(205Pb)/n(238u)年龄为264~487Ma,Ⅷ(Th)/w(U)为0.4~0.8,其中有6颗锆石的N(176Hf)/N(177Hf)初始值为0.281934~0.282292,埘应的EHf(f)值为9.4~-16.4,为典型的壳源岩浆锆石,另外2个测点(BQG-014,BQG-021)的N(176Hf)/N(177Hf)为0.282722~0.282798,对应的εHf(f)值为4.5~6.3,为典型的幔源岩浆锆石;有15颗锆石记录厂元古代-太古代的年龄信息,N(207Pb)/N(206Pb)年龄主要为1713~2559Ma,N(176Hf)/N(177Hf)初始值为0.281288~0.282263,对应的εHf(t)值为-1.3~8.7,绝大部分锆石的εHf(t)值大于2,显示出幔源岩浆锆行的特征。根据锆石Hf同位素组成,BQG-014和BQG-021样品为典型的幔源岩浆锆石,因此,其形成年龄(264~295Ma)应代表了勉略洋消减过程中一次重要的大陆弧岩浆作用时间。  相似文献   

5.
对西藏西部日土县城以南-拉梅拉山口一带的花岗岩体开展了详细的岩相学、岩石地球化学和锆石U-Pb年代学及Hf同位素研究。所有样品铝饱和指数A/CNK集中在0.76~1.0之间,为准铝质类型。CIPW标准矿物组合为Q+Or+Ab+An+Di(或C)+Hy。在稀土元素配分图中呈现出右倾缓倾斜型的特征,轻稀土元素富集并出现较强的分馏作用,重稀土元素无分馏-轻微分馏。δEu在0.56~0.99范围之间,属于铕亏损型。大离子亲石元素出现分化,富集Rb、Pb、Th而亏损K、Ba,高场强元素Nb、Ta、Ti等明显亏损。获得钾长花岗岩、二长花岗岩及花岗闪长岩中岩浆结晶锆石的LA-ICP-MS U-Pb年龄分别为:79.4±0.4Ma、 81.0±0.5Ma和81.3±0.5Ma,结合锆石稀土元素和岩浆振荡环带特征及Th/U比值,上述年龄结果可代表岩石的结晶年龄,表明该套岩体为晚白垩世侵位的大型岩基。两件样品的锆石均具有正的Hf同位素初始比值εHft),两阶段Hf模式年龄(tDM2)分别介于547.5~658.0Ma、523.4~710.2Ma之间。分析认为该套岩体的物质来源应该为富角闪石的下地壳,可能为幔源岩浆首先侵入到地壳基底岩石中形成新生地壳,然后在温度约为700~800℃之间、压力<8kbar且富含流体的影响下,这种既有新生地壳又有古老基底地壳构成的混合地壳发生部分熔融而形成。这一结论与野外宏观露头上岩体中大量发育暗色微粒包体等直接岩石学证据相佐证。结合区域构造演化及岩体所处的大地构造位置,该套花岗岩体应该形成于洋壳闭合时的碰撞造山过程,其形成与侵位与北侧班公湖-怒江结合带的构造演化有成因上的联系,是班公湖-怒江特提斯洋向南的俯冲碰撞的产物。  相似文献   

6.
冀北小张家口超基性岩体的锆石U-Pb年龄和Hf同位素组成   总被引:6,自引:5,他引:6  
采用离子探针(SHRIMPⅡ)测得小张家口基性-超基性岩体中的锆石主要有220±5Ma和491±7Ma两组年龄,以及一个很老的继承锆石年龄2453Ma。年龄为220±5Ma的一组锆石(A组)具有典型的岩浆型振荡环带,这组年龄应代表该岩体的侵位年龄。A组锆石的~(176)H/~(177)Hf比值从0.282557到0.282690,ε_(Hf)(220Ma)=-2.9~ 1.66。年龄为491±7Ma的一组锆石(B组)具有变质成因的蝴蝶结构(Butterfly structure)和熔蚀边,属于继承锆石。B组锆石的~(176)Hf/~(177)Hf比值从0.282239到0.282483,ε_(Hf)(491Ma)=-8.6~0.06。~(207)Pb/~(206)Pb年龄为2453Ma的锆石应该是岩浆侵位时从华北克拉通古元古代基底中捕获的锆石。A组锆石的Hf同位素数据表明,220Ma左右由于华北北缘岩石圈伸展,导致软流圈地幔上涌,亏损的软流圈地幔流/熔体与富集的岩石圈地幔相互作用并混合,这种混合地幔源区发生部分熔融而形成小张家口基性-超基性岩体。B组锆石可能是小张家口岩体在岩浆侵位过程中捕获的来源于富集地幔或大陆下地壳的锆石。  相似文献   

7.
对班戈县北部马前乡地区的早白垩世安山岩和英安岩进行了详细的地质填图及岩石学、年代学、地球化学和Hf同位素研究。锆石U-Pb定年获得安山岩年龄分别为(108.0±1.5)Ma和(113.6±0.9)Ma;英安岩年龄为(106.7±1.9)Ma和(113.6±0.8)Ma。安山岩富集Th和U,亏损Nb、Ta和Ti,具有变化范围较大的Mg#值(25~63),锆石εHft)值(-8.6~+1.5)以负值为主,应当为幔源镁铁质熔体与壳源熔体的混合产物。英安岩具有与安山岩类似的微量元素成分特征及负的锆石εHft)值(-12.3~-8.1),应当是地壳部分熔融的产物。结合前人研究成果认为,这些早白垩世岩浆岩是约110 Ma沿班公湖-怒江缝合带岩浆大爆发的产物,可能与班公湖-怒江洋闭合之后的拉萨与羌塘地块陆-陆碰撞有关。  相似文献   

8.
徐楠  吴才来  赵苗苗  刘畅 《地质论评》2023,69(3):2023030025-2023030025
南阿尔金造山带是中国西北地区重要的俯冲—碰撞杂岩带。本文对茫崖地区出露的闪长岩开展岩石学、地球化学、锆石U- Pb年代学和Lu—Hf同位素地球化学研究,探讨其岩石成因和成岩时的构造环境。研究表明,茫崖闪长岩亏损Nb、Ta、Ti、P、Th、U、HREEs、Ba、Sr等元素,富集Rb等大离子亲石元素及LREEs,显示与俯冲相关岛弧岩浆岩相似的地球化学特征。样品的锆石U- Pb年龄为494~461Ma,εHf (t)为0. 01~3. 90,tDM2为1496~1447Ma,少量εHf (t)为负值(-2. 22~-0. 03),tDM2为1453~1254Ma,指示其物质来源以中元古代(1453~1254 Ma)新生地壳物质为主,混合少量中元古代(1496~1447Ma)古老地壳物质。综上,该期岩浆活动是幔源岩浆的底侵作用导致下地壳熔融的产物,指示南阿尔金造山带在<494Ma进入深俯冲陆壳断离—折返阶段,同时伴随着大规模幔源岩浆的底侵作用,茫崖闪长岩是深俯冲陆壳断离后折返作用的岩浆活动响应。  相似文献   

9.
吕梁地区在华北克拉通前寒武纪研究中具有重要位置,出露大量的古元古代变质表壳岩和花岗质岩石,对研究华北克拉通古元古代地质演化历史具有重要意义。本次研究选择吕梁地区白家滩花岗片麻岩进行锆石和独居石U-Pb年代学以及锆石Hf同位素研究,2个花岗片麻岩的岩浆锆石U-Pb年龄分别为2182±16Ma和2185±24Ma,代表了其侵位时代。独居石U-Pb年龄分别为1898±7Ma和1899±14Ma,明显比锆石增生边的谐和207Pb/206Pb年龄(2180~2032Ma)年轻,说明独居石对后期变质作用的响应程度比锆石强,其U-Pb年龄更能反映白家滩花岗片麻岩经历了~1900Ma的退变质作用,与华北克拉通中部造山带的变质作用时间一致。花岗片麻岩的锆石Hf同位素亏损地幔模式年龄(tDM)为2473~2598Ma,两阶段亏损地幔模式年龄(tDMC)分别为2646~2839Ma,εHft)值分布于-1.3~+1.8之间,未显示同期幔源物质的加入,而是新太古代地壳物质部分熔融的产物,结合已有的古元古代中期(2.2~2.1Ga)的岩浆岩锆石Hf同位素数据,华北克拉通新太古代地壳在2.2~2.1Ga期间发生了广泛的重熔作用,这期岩浆活动在华北克拉通吕梁、中条、五台以及胶-辽-吉等地区广泛发育,可能形成于陆内裂谷环境。  相似文献   

10.
本文对冈底斯岩浆带中段谢通门塔玛地区碱长花岗岩进行了原位LA-ICP-MS锆石U-Pb定年和LA-MCICP-MS锆石Lu-Hf同位素分析。研究结果表明,采自该岩体不同部位的两件锆石U-Pb同位素加权平均年龄分别为(40.02±0.39)Ma和(40.65±0.32)Ma,具有几乎一致的地质年龄,即碱长花岗岩侵位结晶年龄为40 Ma左右。LA-MCICP-MS锆石Lu-Hf同位素研究显示,176Hf/177Hf比值在0.282633~0.282878,平均值为0.282765,计算所得的εHf(t)值介于-4.08~4.15,平均值为0.28,峰值在-1~+1之间;TDMC模式年龄在822~1373 Ma,平均值为1075 Ma,峰值年龄为1000~1200 Ma。其次,样品的εHf(t)值具有正负相间的特点,εHf(t)也相对较小,为典型的壳幔混染型,岩浆源区主要以古老地壳的熔融为主。综合研究表明,谢通门塔玛地区碱长花岗岩主要是由新特斯洋板片的断离,致使软流圈地幔上涌,引起拉萨地体地壳物质的熔融、再循环而形成的,在这个过程中有部分幔源物质的加入。  相似文献   

11.
Neoproterozoic magmatism in the Yangtze Block of South China produced voluminous S- and I-type granites, and sparse A-type granites. The Daxiangling A-type granitic pluton is spatially associated with the Shimian I-type pluton at the western margin of the Yangtze Block. Both plutons have similar SHRIMP zircon U-Pb ages of~800 Ma and are slightly younger than the tonalite-trondhjemite-granodiorite (TTG) gneisses in the area.  相似文献   

12.
中国东南沿海与南岭内陆A型花岗岩的对比及其构造意义   总被引:11,自引:1,他引:11  
中国东南部广泛发育中生代A型花岗岩,按其空间展布,可区分为东南沿海和南岭内陆两个岩带。东南沿海A型花岗岩主要形成于晚白垩世(92~103Ma),时间跨度不大,而南岭内陆A型花岗岩起始时间早,延续时间长(186~124Ma),自早侏罗世至早白垩世均有发育。东南沿海A型花岗岩可区分为过碱性和铝质两种类型,但南岭内陆A型花岗岩基本均属铝质类型。与南岭内陆A型花岗岩相比,东南沿海A型花岗岩相对富SiO2,富Na2O,而K20,Rb,Sr,Ba含量及FeO*/(FeO*+MgO)比值则相对偏低。Nd同位素示踪指示两带A型花岗岩均为壳幔混熔岩浆经高度分异演化结晶的产物,但不同地区A型花岗岩因区域引张程度不同,导致幔壳物质混熔比例存在差异。通过对两带A型花岗岩共生岩石组合及产出构造背景的综合分析,认为东南沿海A型花岗岩形成于与古太平洋板块西向俯冲有关的弧后伸展引张环境,而南岭内陆A型花岗岩的产出则主要受板内裂谷环境控制,可能与古特提斯及古太平洋构造域的联合制约有关。  相似文献   

13.
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   

14.
福建沿海晚中生代花岗质岩石成因及其地质意义   总被引:4,自引:2,他引:2  
福建白云山、鼓山和石牛山均位于福建沿海地带,该区域花岗岩类分布广泛。LA-ICP-MS锆石U-Pb定年结果显示,白云山、鼓山(魁歧)和石牛山地区花岗岩年龄分别为99.3Ma±1.8Ma、99.4Ma±2.3Ma和94.7Ma±1.4Ma,属晚白垩世早期的产物。花岗岩均具有富硅、富碱、贫钙镁、高分异指数等特点,属弱过铝到准铝质岩石。稀土元素具中-强Eu负异常,总体呈现轻稀土元素富集的右倾“V型”模式。微量元素Rb、U、Th、La等强烈富集,相对亏损Ba、Sr、P、Ti等元素。岩相学和地球化学特征分析表明,研究区花岗岩属典型的A型花岗岩,其中魁歧花岗岩为碱性A型花岗岩,其余地区为铝质A型花岗岩。研究表明,研究区A型花岗岩具有相似的源区组成;岩浆来源于地壳物质的部分熔融,并可能有部分地幔物质参与;碱性A型花岗岩较铝质A型花岗岩可能有更多的地幔物质加入。结合地球化学、野外地质、区域背景及年龄资料综合判定,中国东南沿海2类A型花岗岩为古太平洋板块俯冲体系中弧后伸展环境下的产物。  相似文献   

15.
Petrology,geochemistry and genesis of Kuiqi granite batholith   总被引:1,自引:0,他引:1  
The Kuiqi granite batholith outcrops in the vicinity of Fuzhou City, Fujian Province and constitutes one of the typical alkali granitic complexes in the “Belt of Miarolitic Granites” extending along the southeast coast of China. The complex is believed to have been emplaced at higher levels of the crust in a tensional fault environment. Petrographically it is composed mainly of aegirine-arfvedsonite granites with early biotite granites scattered. Miarolitic structure and granophyric texture are commonly observed. The Rb-Sr isochron age of the complex is 107.65 m.y. Both petrological and petrochemical studies show that the Kuiqi granite is of A-type. Data on chemical composition, REE pattern and transition elements reveal that there is a close genetic connection between granites and associated volcanic rocks. Thus, syntexistype (I-type) granite, A-type granite and volcanic rocks form a cogenetic “trinity”, in which the A-type granite is usually the latest member of the volcanic-intrusive series.  相似文献   

16.
《International Geology Review》2012,54(11):1284-1295
Late Cretaceous–early Tertiary granites in the Gyeongsang Basin have distinctly different bulk-rock compositions. Calc-alkaline I-type metaluminous granites display petrographic features implying magma mixing, whereas A-type granites are hypersolvus and peralkaline. I-type plutons mainly consist of enclave-rich granodiorites and enclave-poor porphyritic granites typified by abundant plagioclase phenocrysts; these granitoids contain various mafic clots and magmatic/microgranular enclaves (MMEs). A-type bodies are perthitic alkali-feldspar granites characterized by interstitial annite + riebeckite-arfvedsonite. New SHRIMP-RG zircon U–Pb age dating of an I-type enclave-poor porphyritic granite and an A-type alkali-feldspar granite yielded ages of 65.7 ± 0.7 and 53.9 ± 0.3 million years, respectively. Based on prior geochronologic data and these contrasting ages of granitic magma genesis, SE Korea may have evolved tectonically from latest Cretaceous compression to late Palaeocene extension (i.e. orogenic collapse). The later part of the 66–54 Ma magmatic gap apparently includes the time of tectonic inversion in the SE Korean Peninsula, a far-field effect of the collision of the Indian subcontinent with Eurasia. This process is also reflected in the 69–52 Ma NNE-trending Eurasian apparent polar wandering path.  相似文献   

17.
浙东白垩纪北漳和梁弄花岗岩体及其暗色岩石包体研究   总被引:7,自引:0,他引:7  
浙东地区晚中生代花岗岩类在岩性上分为三类:花岗岩-二长花岗岩、钾长花岗岩和A型花岗岩。对后两类花岗岩已有较多研究,但对前一类,尤其是二长花岗岩的研究还较薄弱。选择浙东具代表性的北漳和梁弄二长花岗岩体及其所含暗色岩石包体,以及共生的石英闪长岩类,通过系统的岩石学与地球化学对比研究,提出浙东二长花岗岩属准铝质、高钾钙碱性Ⅰ型花岗岩类演化系列,暗色岩石包体是由花岗质岩浆在深部析离出的镁铁质微粒包体(MME),成分特征类似于石英闪长岩,说明三者具内在成因联系,均与俯冲作用关系密切。  相似文献   

18.
Two types of spatially and temporally associated Jurassic granitic rocks, I-type and A-type, occur as pluton pairs in several locations in southern Hunan Province, South China. This paper aims to investigate the genetic relationships and tectonic mechanisms of the co-development of distinct granitic rocks through petrological, geochemical and geochronological studies. Zircon LA-ICPMS dating results yielded concordant U–Pb ages ranging from 180 to 148 Ma for the Baoshan and Tongshanling I-type granodiorites, and from 180 to 158 Ma for the counterpart Huangshaping and Tuling A-type granites. Petrologically, the I-type granodiorites consist of mafic minerals such as hornblende whereas the A-type granites are dominated by felsic minerals (e.g., quartz, K-feldspar and plagioclase). Major and trace element analyses indicate that the I-type granodiorites have relatively low SiO2 (64.5–71.0%) and relatively high TiO2 (0.28–0.51%), Al2O3 (13.8–15.5%), total FeO (2.3–4.7%), MgO (1.3–2.6%) and P2O5 (0.10–0.23%) contents, and the A-type granites are characterized by high concentrations of Rb (212–1499?ppm), Th (18.3–52.6?ppm), U (11.8–33.6?ppm), Ga (20.0–36.6?ppm), Y (27.1–134.0?ppm) and HREE (20.3–70.0?ppm), with pronounced negative Eu anomalies (Eu/Eu*?=?0.01–0.15). Moreover, the I-type granodiorites are classified as collision-related granites emplaced under a compressional environment, whereas the A-type granites are within-plate granites generated in an extensional setting. Zircon Hf isotopic compositions vary substantially for these granitic rocks. The I-type granodiorites are characterized by relatively young Hf model ages (TDM1?=?1065–1302 Ma, TDMC =1589–2061 Ma) and moderately negative εHf(t) values (–5.9 to –11.5), whereas the A-type granites have very old model ages (TDM1?=?1454–2215 Ma, TDMC?=?2211–2974 Ma) and pronounced negative εHf(t) values (–15.8 to –28.3). These petrochemical and isotopic characteristics indicate that the I-type granodiorites may have been derived from a deep source involving mantle-derived juvenile (basaltic) and crustal (pelitic) components, whereas the A-type granites may have been sourced from melting of meta-greywacke in the crust. This study proposes that the pressure and temperature differences in the source regions caused by combined effects of intra-plate mantle upwelling and plate subduction are the major controlling factors of the co-development of the two different types of magmas. Crustal anatexis related to lithospheric delamination and upwelling of hot asthenosphere under a high pressure and temperature environment led to the formation of the I-type magmas. On the other hand, the A-type magmas were formed from melting of the shallower part of the crust, where extensional stress was dominant and mantle-crust interaction was relatively weak. Rifts and faults caused by mantle upwelling developed from surface to depth and successively became channels for the ascending I- and A-type magmas, resulting in the emplacement of magmas in adjacent areas from sources at different depths.  相似文献   

19.
太姥山和鼓山位于福建东南沿海地带。岩石学和岩相学研究表明太姥山地区和鼓山地区花岗岩分属铝质A型花岗岩和碱性A型花岗岩。锆石LA-ICP-MS U-Pb同位素定年结果表明,两地区花岗岩成岩年龄分别为(96.6±1.6)Ma(MSWD=0.65)和(99.4±2.3)Ma(MSWD=0.49),成岩时代均属晚白垩世早期。结合中国东部沿海两类A型花岗岩,讨论了它们在岩石学、岩相学、地球化学及其判别图解上的区别。总体上认为,碱性A型花岗岩在AKI值、TFeO/MgO比值、104×Ga/Al以及(Zr+Nb+Ce+Y)值上均大于同区域的铝质A型花岗岩,但上述化学指标的数值也存在一定范围的重叠;且传统A型花岗岩判别图解不完全适用于强分异的铝质A型花岗岩。地球化学特征表明,两地区A型花岗岩应具有相似的源区,即岩浆起源于地壳物质熔融,同时成岩过程有一定的地幔物质参与。但鼓山地区碱性A型花岗岩较太姥山地区铝质A型花岗岩有更多地幔物质的加入,导致前者显示出部分幔源岩浆起源的特征。结合地球化学、野外地质、区域背景及年代学综合判定,两地区花岗岩成因与古太平洋板块对欧亚板块的俯冲角度密切相关,均属于弧后拉伸体制之下的构造环境。  相似文献   

20.
In the Lachlan Fold Belt of southeastern Australia, Upper Devonian A-type granite suites were emplaced after the Lower Devonian I-type granites of the Bega Batholith. Individual plutons of two A-type suites are homogeneous and the granites are characterized by late interstitial annite. Chemically they are distinguished from I-type granites with similar SiO2 contents of the Bega Batholith, by higher abundances of large highly charged cations such as Nb, Ga, Y, and the REE and lower Al, Mg and Ca: high Ga/Al is diagnostic. These A-type suites are metaluminous, but peralkaline and peraluminous A-type granites also occur in Australia and elsewhere. Partial melting of felsic granulite is the preferred genetic model. This source rock is the residue remaining in the lower crust after production of a previous granite. High temperature, vapour-absent melting of the granulitic source generates a low viscosity, relatively anhydrous melt containing F and possibly Cl. The framework structure of this melt is considerably distorted by the presence of these dissolved halides allowing the large highly charged cations to form stable high co-ordination structures. The high concentration of Zr and probably other elements such as the REE in peralkaline or near peralkaline A-type melts is a result of the counter ion effect where excess alkali cations stabilize structures in the melt such as alkali-zircono-silicates. The melt structure determines the trace element composition of the granite. Separation of a fluid phase from an A-type magma results in destabilization of co-ordination complexes and in the formation of rare-metal deposits commonly associated with fluorite. At this stage the role of Cl in metal transport is considered more important than F.  相似文献   

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