2013, Vol. 29
辽东半岛位于胶-辽-吉活动带与辽南-狼林地块的复合交接部位,区内花岗质和镁铁质岩石广泛分布,由于区域上与之相关的金属矿产极为发育,因而深入了解这些侵入岩的岩石成因及其形成的构造环境,成为充分理解该区地球动力学演化的理想“窗口”。近年来,大量高精度同位素年代学资料表明,这些花岗质岩石主要形成于早前寒武纪(2176~1843Ma)(“辽吉花岗岩”,蔡剑辉等,2002;路孝平等,2004;Lu et al., 2006;Li et al., 2007;杨进辉等,2007a)和中生代,后者可进一步划分为晚三叠世(233~200Ma)、侏罗纪(190~156Ma)和早白垩世(140~110Ma)(Yang et al., 2004;Wu et al., 2005;吴福元等, 2005, 2006;杨进辉等,2007b;Pei et al., 2011a),部分镁铁质-超镁铁质岩石形成于(137~129Ma)(Pei et al., 2011b)。然而,这些研究成果多集中在吉南-辽南和辽西东南部地区,相比之下,有关辽东南地区侵入岩的研究程度明显薄弱。吴福元等(2005)对辽南金州地区太古宙片麻岩中原作为太古宙混合岩化产物的大量花岗岩脉体的研究表明它们形成于早白垩世(~125Ma),而有关辽东南地区原划于印支期的卧龙泉和矿洞沟岩体的研究表明它们应形成于早前寒武纪(~1850Ma,许保良等,1998;蔡剑辉等,2002;路孝平等,2004;杨进辉等,2007a),此外,辽东南地区还发育有大量原划为前震旦纪的“混合”花岗岩和少量辉长岩,其时代、成因及构造背景也一直存在较大争议(辽宁省地质矿产局,1989),这严重制约了对区域构造演化历史的深化认识。因此,本文选取辽东南丹东地区出露较广的原定前震旦纪“混合”花岗质岩石及辉长岩进行了系统的年代学和岩石地球化学研究,并结合区域资料探讨其形成的构造环境。
1 区域地质背景辽东半岛位于郯庐断裂以东、华北克拉通东部陆块的东北缘,北邻海西期兴蒙造山带,南部隔渤海湾与苏鲁超高压变质带相接(图 1a)。该区基底岩石主要由北部辽北-吉南太古宙杂岩(龙岗地块)、南部金州太古宙杂岩(辽南地块,向南可能与朝鲜狼林地块相连)和位于其间的辽河群与辽吉花岗岩(胶-辽-吉古元古代活动带)组成,之上广泛出露新元古代-震旦系沉积岩,中生代岩浆岩和火山岩在辽东地区广泛发育(辽宁省地质矿产局,1989)。本文研究区--辽宁省丹东地区即位于辽南-狼林地块与胶-辽-吉活动带的复合部位,区内出露有大量前震旦纪花岗岩、混合花岗岩和少量辉长岩,其中辉长岩主要侵位于辽河群中,部分与混合花岗岩相伴生(图 1b)。本文所选样品采样点如图 1所示,具体的采样位置和岩相学特征如下文。
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图 1 辽东南丹东地区构造位置(a)和研究区地质简图及采样位置(b) Fig. 1 The tectonic location (a) and geological map (b) of the Dandong in southeastern Liaoning Province, including representative sample locations |
样品(DD02-1)采自丹东市西部汤池镇西北约6km的腰岭子沟“混合岩”岩体(坐标:E 124°12′03″,N 40°06′36″;图 1b)。岩体平面呈椭圆状,出露面积约10km2,新鲜面呈灰白色,中粗粒花岗结构,块状构造,主要矿物成分由石英(25%)、碱性长石(40%)、斜长石(30%)、黑云母(3%)和普通角闪石(1%)组成,副矿物由锆石、榍石及不透明矿物等组成(1%),表明该“混合岩”岩性应为二长花岗岩(图 2a)。岩体东部和南部与古元古代辽河群、北部和西部与原定前震旦纪“角闪质条痕状混合岩”均呈不整合接触,其时代被置于前震旦纪(辽宁省第一(区域地质)测量队,1974①)。
①辽宁省第一区域地质测量队.1974. 1:20万丹东-龙岩浦幅区域地质调查报告
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图 2 研究区早白垩世侵入岩体代表性样品的显微照片 (a)-二长花岗岩;(b)-角闪石黑云母二长花岗岩;(c)-角闪辉长岩;(d)-黑云母二长花岗岩.Pl-斜长石;Kfs-钾长石;Qtz-石英;Bt-黑云母;Amp-角闪石 Fig. 2 Micrographs of representative samples for Early Cretaceous intrusive rocks in the studied region (a)-monzogranite; (b)-hornblende biotite monzogranite granite; (c)-amphibole gabbro; (d)-biotite granite. Pl-plagioclase; Kfs-potassium feldspar; Qtz-quartz; Bt-biotite; Amp-amphibole |
样品(DD04-1)采自丹东市西北部汤山城镇西约16km的卜家沟“角闪质条痕状混合岩”岩体(坐标:E 124°00′09″,N 40°19′36″;图 1b)。该岩体平面展布呈北北东向,出露面积约55km2,新鲜面呈浅灰色,中细粒花岗结构,弱片麻状构造,主要矿物成分由石英(25%)、碱性长石(20%)、斜长石(35%)、黑云母(10%)和普通角闪石(7%)组成,副矿物由锆石、榍石及不透明矿物等组成(3%),表明该“角闪质条痕状混合岩”岩性应为角闪石黑云母二长花岗岩(图 2b)。该岩体呈岩墙状产出,内部发育有花岗斑岩脉,周围与古元古代辽河群及原定前震旦纪混合岩和晚侏罗世花岗岩均呈不整合接触,其时代被置于前震旦纪(辽宁省第一测量队,1974)。
样品(DD08-1)采自丹东市北部宽甸县长甸镇西北约17km的湾家甸辉长岩岩体(坐标:E 124°37′26″,N 40°31′28″;图 1b)。该岩体规模相对较小,新鲜面呈灰黑色,细粒辉长结构,块状构造,主要矿物为普通角闪石(40%)和斜长石(54%),部分角闪石具有绿泥石化蚀变,铁质析出,副矿物以磷灰石、磁铁矿和不透明矿物为主(6%),表明其岩性应为角闪辉长岩(图 2c)。该岩体呈岩株状产出于古元古代辽河群中,局部与混合岩相伴生,1:50万区域地质志将其置于三叠纪(辽宁省地质矿产局,1989),而在区域地质调查报告中则被置于前震旦纪(辽宁省第一测量队,1974)。
样品(DD08-2)采自丹东市北部宽甸县长甸镇西北约17km的湾家甸“混合花岗岩”岩体(坐标:E 124°37′26″,N 40°31′28″;图 1b)。该岩体新鲜面呈灰白色,中细粒花岗结构,块状构造,主要矿物成分由石英(30%)、碱性长石(22%)、斜长石(40%)、黑云母(6%)和普通角闪石(1%)组成,副矿物由锆石、榍石及不透明矿物等组成(1%),表明其岩性应为黑云母二长花岗岩(图 2d)。前人(辽宁省第一测量队,1974)中将其置于前震旦纪。
2 分析方法本文样品在河北省廊坊区域地质调查研究所采用常规方法进行粉碎,并用浮选和电磁选方法进行分选,在双目镜下挑选出晶形较好,无明显裂痕和包体的锆石颗粒,然后将其粘贴在环氧树脂表面,打磨抛光后进行透射光和反射光图像采集。锆石阴极发光(CL)图像的采集是在中国地质科学院地质研究所北京离子探针中心采用GATAN公司Chroma阴极发光探头的HTACHI S-3000N扫描电镜上完成。锆石LA-ICP-MS U-Pb原位定年及微区微量、稀土元素分析在中国地质大学(北京)地学实验中心元素地球化学实验室进行。分析仪器采用由美国New Wave Research公司生产的激光剥蚀进样系统(UP193SS)和美国AGLENT科技有限公司生产的Agilent 7500a型四级杆等离子体质谱仪联合构成的激光等离子质谱仪,实验中采用He作为剥蚀物质的载气。分析时采用10Hz的激光频率,193μm的激光波长,36μm的激光束斑直径,激光预剥蚀时间和剥蚀时间分别为5s和45s,U、Th、Pb元素积分时间为20ms,其它元素积分时间为15ms。年龄计算时以国际标准锆石91500为外标进行同位素比值校正,以TEM为监控盲样;元素含量以国际标样NIST612为外标,29Si为内标。测试结果通过GLITTER 4.0软件计算得出,实验获得的数据采用Andersen (2002)的方法进行同位素比值的校正以扣除普通Pb的影响,谐和图的绘制采用ISOPLOT 3.0完成(Ludwig, 2001)。详细的实验分析步骤和数据处理方法见文献Yuan et al.(2004)和Liu et al.(2008a, 2010)。所给定的同位素比值和年龄的误差均在1σ水平。
所采集的样品首先经薄片显微镜下鉴定,然后选择最新鲜的样品用于地球化学分析。样品的粉碎加工均在无污染设备中进行。主量元素和痕量元素分析在北京国家地质测试分析中心完成。主量元素是用X荧光光谱法(XRF)测定,所用仪器为日本理学3080,误差 < 0.5%;微量元素Zr、Sr、Ba、Zn、Rb和Nb也是用X荧光光谱法完成,所用仪器为Rigaku-2100,误差分别为Ba=5%,其他元素 < 3%;稀土元素及V、Cr、Ni、Co、Cu、Pb、U、Th、Ta和Hf用TJA-PQ-ExCell等离子体光质谱仪分析完成,误差 < 5%。
3 分析结果 3.1 锆石U-Pb年代学辽东南丹东地区早白垩世侵入岩中锆石的微量、稀土元素分析和LA-ICP-MS U-Pb定年结果分别见表 1和表 2,部分锆石的阴极发光(CL)图像见图 3,锆石稀土元素球粒陨石标准化配分图解和U-Pb谐和图分别见图 4和图 5。
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表 1 辽东南丹东地区早白垩世侵入岩中锆石稀土元素和微量元素成分特征(×10-6) Table 1 Mean LA-ICP-MS trace-element composition (×10-6) for the Early Cretacous intrusive rocks in Dandong area of southeastern Liaoning Province |
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图 3 研究区早白垩世侵入岩中部分锆石阴极发光图像 Fig. 3 CL images of the selected zircons from the Early Cretaceous intrusive rocks in the studied area |
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图 4 研究区早白垩世侵入岩中锆石稀土元素球粒陨石标准化配分图解(标准化值据Boynton, 1984) Fig. 4 Chondrite-normalized REE patterns for the Early Cretaceous intrusive rocks in the studied area (normalizing data after Boynton, 1984) |
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图 5 研究区早白垩世侵入岩中锆石LA-ICP-MS U-Pb年龄谐和图 Fig. 5 U-Pb concordia diagrams summarizing the LA-ICP-MS zircon data for the Early Cretacous intrusive rocks in the studied area |
腰岭子沟二长花岗岩(DD02-1)中锆石粒径介于150~400μm之间,多为自形-半自形长柱状或短柱状晶形。锆石CL图像显示,内部结构清晰,均发育典型成分环带(图 3a),而从表 1中可以看出,23颗锆石的U=59×10-6~603×10-6,Th=79×10-6~657×10-6,Lu=27×10-6~176×10-6,Hf=8155×10-6~11690×10-6,其Th/U比值介于0.53~2.18之间,Lu/Hf比值介于0.00309~0.00975之间,稀土元素配分图解中显示LREEs明显亏损,而HREEs明显富集,且具有明显的负Eu异常和正Ce异常等特点(图 4a),上述特征均表明其具有典型岩浆锆石成因特点(Belousova et al., 2002; Hoskin and Ireland, 2000;刘福来等,2009)。LA-ICP-MS锆石U-Pb定年结果显示,23个测点均位于谐和线上或附近,其206Pb/238U年龄值介于133~127Ma之间(表 2),加权平均年龄为129±1Ma (MSWD=0.28)(图 5a),表明该二长花岗岩岩体的形成时代应为早白垩世。
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表 2 辽东南丹东地区早白垩世侵入岩锆石LA-ICP-MS U-Pb分析结果 Table 2 LA-ICP-MS zircon U-Pb dating data for the Early Cretacous intrusive rocks in Dandong area of southeastern Liaoning Province |
卜家沟角闪石黑云母二长花岗岩(DD04-1)中锆石可以分为半自形长柱状和椭圆状两种,前者粒径介于150~350μm之间,CL图像显示其具有条痕状吸收特点,而后者粒径介于50~180(m之间,发育典型成分环带(图 3b);锆石微区成分分析结果显示,19颗锆石均具有较高的U (75×10-6~710×10-6)、Th (63×10-6~466×10-6)含量及Th/U比值(0.63~1.15),其Lu=25×10-6~92×10-6,Hf=7645×10-6~11668×10-6,Lu/Hf比值介于0.00281~0.00820之间(表 1),并且以明显亏损LREEs、富集HREEs和具有明显负Eu异常及正Ce异常为特征(图 4b),暗示其岩浆成因特点(Belousova et al., 2002; Hoskin and Ireland, 2000;刘福来等,2009)。锆石U-Pb定年结果表明,19个测点均位于谐和线上,其206Pb/238U年龄值介于134~121Ma之间(表 2),加权平均年龄为126±1Ma (MSWD=0.60)(图 5b),表明该角闪石黑云母二长花岗岩岩体的形成时代应为早白垩世。
湾家甸角闪辉长岩(DD08-1)中锆石多呈半自形-他形板状,粒径介于80~200μm之间。CL图像显示,除个别锆石发育宽缓成分环带外,多具有条痕状吸收特点(图 3c);微区成分分析结果显示,18颗锆石的U=122×10-6~1053×10-6,Th=114×10-6~2077×10-6,Lu=33×10-6~175×10-6,Hf=5962×10-6~8363×10-6,其Th/U比值介于0.82~2.40之间,Lu/Hf比值介于0.00424~0.02504之间,并且以明显亏损LREEs、富集HREEs和具有明显负Eu异常及正Ce异常等特征(图 4c),暗示其岩浆成因特点(Belousova et al., 2002; Hoskin and Ireland, 2000;刘福来等,2009)。锆石U-Pb定年结果显示,所选18个测点均位于谐和线上或附近,其206Pb/238U年龄值介于130~123Ma之间(表 2),加权平均年龄为127±1Ma (MSWD=0.78)(图 5c),表明该角闪辉长岩岩体的侵位时代应为早白垩世。
湾家甸黑云母二长花岗岩(DD08-2)中锆石主要呈半自形短柱状或长柱状和椭圆状,其粒径介于50~180μm之间,Cl图像显示其均发育成分生长环带(图 3d),从表 1中可以看出,19个测点的U=251×10-6~4573×10-6、Th=223×10-6~7991×10-6、Lu=71×10-6~348×10-6,Hf=8234×10-6~13636×10-6,其Th/U比值和Lu/Hf比值分别介于0.57~1.75和0.00835~0.03594之间,结合其明显亏损LREEs、富集HREEs以及具明显负Eu异常和正Ce异常等特征(图 4d),暗示其典型岩浆成因特点(Belousova et al., 2002; Hoskin and Ireland, 2000;刘福来等,2009)。锆石U-Pb定年结果表明,19个测点均位于谐和线上,其206Pb/238U年龄值介于128~121Ma之间(表 2),加权平均年龄为123±1Ma (MSWD=0.94)(图 5d),表明该花岗岩岩体应侵位于早白垩世。
3.2 地球化学 3.2.1 主量元素本文所选辽东南丹东地区早白垩世侵入岩样品的主量和微量元素分析结果见表 3。该区早白垩世花岗质岩石主要由二长花岗岩、黑云母二长花岗岩和角闪石黑云母二长花岗岩组成,其SiO2含量为66.99%~73.13%,MgO=0.45%~2.61%,Mg#值为29~56,Al2O3=13.97%~14.92%,CaO=1.33%~2.97%,Na2O=3.26%~3.60%,K2O=3.52%~4.67%,K2O/Na2O=1.01~1.43(表 3)。在TAS图解上该样品落在花岗岩和花岗闪长岩区域内,属于亚碱性系列(Irvine and Baragar, 1971)(图 6),而在SiO2-K2O变异图解中则落入高钾钙碱性系列区内(Ringwood,1975;图略),其A/CNK=1.00~1.06,A/NK=1.30~1.56,这些特征均可与吉南地区六道沟、绿江村及榆树林子弱过铝质的I型花岗质岩石特征相对比(Pei et al., 2011a),而明显不同于辽宁千山同时期A型花岗岩(图 6)(Wu et al., 2005;Yang et al., 2006)。
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表 3 辽东南丹东地区早白垩世侵入岩的主量元素(wt%)和痕量元素(×10-6)分析结果 Table 3 Major (wt%) and trace elements (×10-6) data for the Early Cretacous intrusive rocks in Dandong area of southeastern Liaoning Province |
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图 6 研究区早白垩世侵入岩TAS图解(曲线上方为碱性系列,下方为亚碱性系列,据Irvine and Baragar, 1971) 方城-费县玄武岩引自Zhang et al.(2002)、裴福萍等(2004)和Gao et al.(2008);千山A型花岗岩引自Wu et al.(2005)和Yang et al.(2006);吉南弱过铝花岗岩和通化-杨木川基性岩引自Pei et al.(2011a, b) Fig. 6 TAS diagram for the Early Cretaceous intrusive rocks in the studied area (The boundary between alkaline and subalkaline series is after Irvine and Baragar, 1971) Fangcheng-Feixian basalts are from Zhang et al. (2002), Pei et al. (2004) and Gao et al. (2008); Qianshan A-type granites are from Wu et al. (2005) and Yang et al. (2006); the granites of southern Jilin Province and Tonghua-Yangmuchuan mafic rocks are from Pei et al.(2011a, b) |
研究区早白垩世角闪辉长岩SiO2=50.22%,MgO=10.61%,Mg#值为69,Al2O3=14.81%,CaO=10.68%,Na2O=1.95%(K2O/Na2O=0.46),TiO2=0.43%,P2O5=0.08%(表 3)。在TAS图解上落入辉长岩区域内,属于亚碱性系列(Irvine and Baragar, 1971)(图 6a),而在SiO2-K2O变异图解中则落入中钾钙碱性系列区内(Ringwood,1975)。分析结果显示,该区角闪辉长岩主元素特征均与吉南通化早白垩世三棚甸子和辽南杨木川辉长岩相似(图 6)(Pei et al., 2011b),而较低的TiO2和P2O5含量区域上也可与同时代鲁西费县、方城玄武岩(Zhang et al., 2002;裴福萍等,2004;Gao et al., 2008)和胶东地区镁铁质岩脉(Yang et al., 2004)相类似,但K2O含量较低。上述特征与燕辽一带京北南口-延庆古崖居早白垩世基性岩墙群(邵济安等,2001; 邵济安和张履桥,2002)和苏鲁造山带煌斑岩脉较高的TiO2和K2O含量明显不同(Guo et al., 2004, 2007)。
3.2.2 微量元素从稀土元素球粒陨石标准化配分图解中可以看出,研究区早白垩世花岗质岩石稀土元素配分曲线呈明显右倾型,轻重稀土分馏明显,以富集LREEs、亏损HREEs和具有中等负铕异常为特征(图 7a),其稀土元素总量(ΣREE)介于173.5×10-6~193.4×10-6之间,LREE/HREE=17.33~33.29,(La/Yb)N=22.23~38.38,δEu=0.61~0.71(表 3);而从微量元素原始地幔标准化蛛网图中可知,花岗质岩石明显富集Ba、Th、U、K等大离子亲石元素(LILEs),强烈亏损Nb、Ta、P、Ti等高场强元素(HFSEs)(图 7b)。上述特征也都与吉南地区六道沟、绿江村及榆树林子弱过铝质花岗岩相似(图 7a, b;Pei et al., 2011a),与Andean型弧火山岩可对比(Kelemen et al., 2003)。
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图 7 研究区早白垩世侵入岩的球粒陨石标准化配分图解(a,c)和微量元素原始地幔标准化蛛网图(b,d)(球粒陨石标准化值据Boynton, 1984; 原始地幔标准化值据Sun and McDonough, 1989) 方城-费县玄武岩引自Zhang et al.(2002)、裴福萍等(2004)和Gao et al.(2008);千山A型花岗岩引自Wu et al.(2005)和Yang et al.(2006);吉南弱过铝花岗岩和通化-杨木川基性岩引自Pei et al.(2011a, b) Fig. 7 Chondrite-normalized REE patterns (a, c, normalizing data after Boynton, 1984) and primitive mantle-normalized trace element spider diagrams (b, d, normalizing data after Sun and McDonough, 1989) for the Early Cretaceous intrusive rocks in the studied area Fangcheng-Feixian basalts are from Zhang et al. (2002), Pei et al. (2004) and Gao et al. (2008); Qianshan A-type granites are from Wu et al. (2005) and Yang et al. (2006); the granites of southern Jilin Province and Tonghua-Yangmuchuan mafic rocks are from Pei et al.(2011a, b) |
研究区早白垩世角闪辉长岩痕量元素分析结果及其稀土元素球粒陨石标准化配分图解显示,其ΣREE=77.73×10-6,LREE/HREE=8.28,(La/Yb)N=10.42,稀土元素配分曲线呈平缓的右倾型,相对富集LREEs、亏损HREEs,并具有弱的负铕异常(δEu=0.96)(图 7c)。该辉长岩稀土元素含量较低,与吉南通化三棚甸子和辽南杨木川辉长岩相近(27.2×10-6~111×10-6;Pei et al., 2011b),而明显低于鲁西同时期方城-费县玄武岩(425×10-6~562×10-6)(图 7c,Zhang et al., 2002;裴福萍等,2004;Gao et al., 2008)。在微量元素原始地幔标准化蛛网图中可以看出,该区角闪辉长岩相对富集Rb、Ba、Th、U等LILEs、亏损Nb、Ta、Ti等HFSEs,Cr=196×10-6、Co=44.8×10-6、Ni=73.4×10-6、Zr=68.1×10-6(表 3),均与吉南通化三棚甸子和辽南杨木川辉长岩相近(图 7d;Pei et al., 2011b)。
4 讨论 4.1 辽东南丹东地区早白垩世侵入岩的形成时代前人研究表明,辽东南丹东地区出露有大面积的前震旦纪侵入体,其形成时代的判定主要是依据岩石组合对比及其与围岩的接触关系,即使有少量的K-Ar或Rb-Sr定年资料(辽宁省地质矿产局,1989),然而由于体系封闭温度较低、区域构造演化复杂等因素降低了测试精度,致使其形成时代一直存在较大争议。而我们通过详细的野外地质考察及室内综合研究认为,该区原定前震旦纪腰岭子沟“混合岩”、卜家沟“角闪质条痕状混合岩”、湾家甸“混合花岗岩”和辉长岩岩性应分别为二长花岗岩、角闪石黑云母二长花岗岩、黑云母二长花岗岩和角闪辉长岩。所选样品中锆石CL图像显示,绝大多数锆石呈自形-半自形晶形、发育成分生长环带或具有条痕状吸收特点(图 3),所有锆石的Th (63×10-6~7991×10-6)、U (59×10-6~4573×10-6)含量及其比值(Th/U=0.53~2.40)都比较高(表 1),结合其亏损LREEs、富集HREEs以及具明显负Eu异常和正Ce异常等特征(图 4),表明这些锆石均具有典型岩浆成因特点(Belousova et al., 2002; Hoskin and Ireland, 2000;刘福来等,2009),暗示其形成时代应代表了岩体的侵位时代。对上述四个岩体中锆石的LA-ICP-MS U-Pb定年结果表明,所有测点的206Pb/238U谐和年龄介于134~121Ma之间,其加权平均年龄分别为129±1Ma、126±1Ma、123±1Ma和127±1Ma,峰期年龄为126±1Ma,表明该区所选四个原定前震旦纪(辽宁省第一测量队,1974)侵入岩岩体的形成时代均为早白垩世,这与前人对吉林南部早白垩世火山岩(130~113Ma;Pei et al., 2006;Yu et al., 2009)、吉南-辽东半岛大面积同时代花岗岩(140~110Ma;Wu et al., 2005;Yang et al., 2006;Pei et al., 2011a)及鲁西(133~124Ma;Xu et al., 2004;Yang et al., 2005, 2008)、胶东半岛(132~123Ma;Yang et al., 2004)、苏鲁-大别(130~120Ma;Jahn et al., 1999;Liu et al., 2008b)基性岩等的定年结果相吻合,均指示了华北克拉通、乃至整个中国东部中生代最强烈的早白垩世岩浆-热事件(王德滋和周新民,2002;Xu et al., 2004;Wu et al., 2005)。
4.2 辽东南丹东地区早白垩世侵入岩的岩浆源区性质地球化学分析结果显示,辽东南丹东地区早白垩世花岗质岩石具有I型花岗岩特点(图 6、图 7)(Kelemen et al., 2003),其高硅(66.99%~73.13%)、富钾(K2O/Na2O=1.01~1.43)、富集LREEs和Rb、Ba、Th、U、K等LILEs,亏损HREEs和Eu、Sr、P、Ti等特征,表明其岩浆应起源于下地壳物质的部分熔融。而该区角闪辉长岩SiO2为50.22%、Mg#为69,Cr (196×10-6)、Co (44.8×10-6)、Ni (73.4×10-6)含量都较高,从而说明其岩浆具有幔源成因特点(Frey and Prinz, 1978;Saunders et al., 1992)。研究结果表明,洋中脊(洋岛)玄武岩的Nb/U=47,Ta/U=2.7(Hofmann,1988;Taylor and Mclennan, 1995;Rudnick et al., 2004),地壳的Nb/U=12.1,Ta/U=1.1(Taylor and Mclennan, 1995),而本文角闪辉长岩的Nb/U和Ta/U值分别为8.33和0.57,明显低于洋中脊(洋岛)玄武岩和地壳,而大规模的地壳混染很难会产生如此低的Nb/U和Ta/U值,而且陆壳物质的加入也而会造成岩浆中Nb、Ta含量的升高,这也与本文角闪辉长岩Nb、Ta明显亏损特征不符。因此,本文角闪辉长岩在岩浆演化过程中未遭受陆壳物质混染,这也与岩石中没有残留锆石的特征相一致(图 5和表 2)。然而,与原始幔源岩浆和洋岛玄武岩明显不同,本区角闪辉长岩富集LILEs和不相容元素,明显亏损Nb、Ta、Ti等HFSEs,而Zr、Hf相对REE亏损并不明显(图 7d),说明Nb、Ta、Ti的亏损并非源区金红石等富HFSEs矿物残留所致(Ionov et al., 1999),暗示本区角闪辉长岩的形成可能与洋壳俯冲作用有关(Gill, 1981; Grove and Donnelly-Nolan, 1986;Grove et al., 2003; Eiler et al., 2000;Meng et al., 2011),其岩浆应起源于受俯冲流体交代的岩石圈地幔楔(Meng et al., 2008)。
4.3 辽东南丹东地区早白垩世侵入岩形成的构造意义辽东南丹东地区早白垩世侵入岩主要有花岗质岩石和角闪辉长岩组成,具有双峰式火山岩组合特点。地球化学分析结果显示,角闪辉长岩具有典型弧岩浆作用的特点(图 6、图 7)(Kelemen et al., 2003;Meng et al., 2008, 2011);而花岗质岩石与吉南弱过铝质花岗岩可对比,在Pearce et al. (1984)微量元素Nb-Y和Rb-(Y+Nb)变异图解中也落入火山弧区域内(图 8,Pei et al., 2011a),结合区域地质资料,暗示该区早白垩世双峰式岩浆作用可能与古太平洋板块北西向向欧亚大陆之下的俯冲作用相联系(Wu et al., 2005;Yang et al., 2006;Pei et al., 2011a)。结合研究区东北部吉林省东南部临江地区同时代钙碱性火山岩(Yu et al., 2009)以及辽宁省南部辽南饮马湾山同时代活动陆缘型闪长质岩石的存在(Pei et al., 2011b),表明辽东南丹东地区在早白垩世可能出于一个类似于弧后盆地的伸展环境,这也与该区西北部辽中千山地区发育早白垩世A型花岗岩及北部存在早白垩世双峰式岩浆作用的研究结果(Yang et al., 2006;Yu et al., 2009;Pei et al., 2011a, b)相一致。此外,前人通过对中国东北松辽盆地和大兴安岭地区早白垩世主要由流纹岩类和玄武岩类组成的双峰式火山岩组合(许文良等,1994;林强等,2003;孟恩等,2011)、大别山地区的中生代辉长岩-花岗岩组合(戴圣潜等,2003)以及华北克拉通中生代双峰式岩墙群的研究(邵济安等,2001)表明,早白垩世岩浆-热事件在华北克拉通东部乃至整个中国东部广泛存在(王德滋和周新民,2002;Xu et al., 2004;Wu et al., 2005),因而本区发育的早白垩世侵入岩即是对这一岩浆-热事件的响应。
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图 8 研究区早白垩世侵入岩的微量元素Rb-(Y+Nb)和Nb-Y构造环境判别图解(据Pearce et al., 1984) ORG-洋脊花岗岩;Syn-COLG-同碰撞花岗岩;VAG-火山弧花岗岩;WPG-板内花岗岩;千山A型花岗岩引自Wu et al.(2005)和Yang et al.(2006);吉南弱过铝花岗岩引自Pei et al.(2011a) Fig. 8 Rb-(Y+Nb) and Nb-Y discrimination diagrams of tectonic settings for the Early Cretacous intrusive rocks in the studied area (after Pearce et al., 1984) ORG-oreanic ridge granites; Syn-COLG-syn-collisional granites; VAG-volcanic arc granites; WPG-within plate granites; Qianshan A-type granites are from Wu et al. (2005) and Yang et al. (2006); the granites of southern Jilin Province are from Pei et al. (2011a) |
前人通过对华北克拉通北缘中晚三叠世碱性岩带和东北缘吉南-辽南地区北东向展布的晚三叠世火成岩带的研究结果表明,兴蒙造山带和扬子克拉通在晚三叠世之前对辽东半岛的影响就已经结束(Yang et al., 2006, 2007b;杨富全等,2007;裴福萍等,2008;吴福元等,2008;Xu et al., 2009;杨进辉和吴福元,2009;张拴宏等,2010;Pei et al., 2011b;蔡剑辉等,2011),之后吉南-辽南地区--即研究区北西部应处于碰撞后的伸展环境。而古地磁资料也揭示,早白垩世时(约130Ma)华北、华南与西伯利亚板块的古磁极最终重合(Gilder and Courtillot, 1997),中国东部已经完全处于东部太平洋构造域控制之下。因此,辽东南丹东地区早白垩世侵入岩的形成应与东侧古太平洋板块北西向向亚欧板块之下的俯冲作用相联系(Wu et al., 2005;Yang et al., 2007b;Xu et al., 2009;Pei et al., 2011a, b)。
5 结论通过对辽东南丹东地区早白垩世侵入岩的岩石学、锆石U-Pb年代学和岩石地球化学研究,并结合区域地质资料,得出如下结论:
(1)辽东南丹东地区原定前震旦纪的腰岭子沟“混合岩”、卜家沟“角闪质条痕状混合岩”、湾家甸“混合花岗岩”和辉长岩岩性应分别为二长花岗岩、角闪石黑云母二长花岗岩、黑云母二长花岗岩和角闪辉长岩。LA-ICP-MS锆石U-Pb定年结果表明,它们均形成于早白垩世(峰期为126Ma),而并非前人所定的前震旦纪。
(2)辽东南丹东地区早白垩世侵入岩具有双峰式岩浆作用特点,花岗质岩石应起源于下地壳物质的部分熔融,而角闪辉长岩应起源于受俯冲流体交代的岩石圈地幔楔。
(3)辽东南丹东地区早白垩世侵入岩应形成于类似弧后盆地的伸展环境,其形成应与古太平洋板块北西向向欧亚大陆之下的俯冲作用相联系。
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