新疆阿拉套山花岗岩类的岩石化学

新疆阿拉套山南坡东西向展布的花岗岩石的岩石化学研究表明，本区同时存在Ｉ型和Ｓ型两种类型的花岗岩，其分布受构造环境控制，靠近古板块缝合线为Ｉ型花岗岩分布区、远离古板块缝合线为Ｓ型花岗岩分布区。源岩性质和作用强弱等因素可能是造成岩石化学成分差异的原因。     

中缅毗邻区金腊Pb-Zn-Ag多金属矿田花岗岩锆石U-Pb定年与地球化学特征

位于中缅毗邻区的金腊铅锌银多金属矿田大地构造上处于保山—掸泰地块东缘,勐统—耿马—西盟元古宙—古生代被动大陆边缘活动带南段。与矿化有关的花岗岩(简称金腊花岗岩)包括老厂似斑状角闪二长花岗岩、勐林山似斑状黑云二长花岗岩和南腊碱长花岗斑岩。文中系统研究了上述岩石的主量元素、稀土元素、微量元素、成矿元素和锆石U-Pb同位素年龄等特征,从构造岩浆演化的角度,探讨上述岩体之间内在联系、成因演化以及与成矿的关系:(1)在金腊花岗岩三种岩石类型中,老厂似斑状角闪二长花岗岩和勐林山似斑状黑云二长花岗岩的锆石同位素U-Pb年龄皆为(45±1)Ma,形成于岩浆结晶分异早期阶段的深成环境,而南腊碱长花岗斑岩的锆石同位素U-Pb年龄为(43.41±0.78)Ma,形成于岩浆结晶分异晚期阶段的浅成环境。(2)主量元素和微量元素(稀土元素和某些微量元素(Zr/Hf、Nb/Ta、Rb/Sr、Rb/Ba、K/Rb、(Rb/Yb)N、Sr*、K*和Zr*)),结合U-Pb同位素定年研究表明,本区花岗岩形成于喜马拉雅同碰撞造山成矿作用末期局部拉张构造环境,并分别代表了构造岩浆演化过程中不同演化阶段岩浆分异结晶的产物。(3)上述三类花岗岩样品皆位于S型花岗岩区,但从老厂似斑状角闪二长花岗岩,勐林山似斑状黑云二长花岗岩,到南腊碱长花岗斑岩,样品分布逐渐远离"I"型花岗岩和"S"型花岗岩的分界线,这表明自老厂似斑状角闪二长花岗岩至勐林山似斑状黑云二长花岗岩,到南腊碱长花岗斑岩幔源组分逐渐减少。(4)相对中国花岗岩,南腊碱长花岗斑岩不仅更富集W、Cu、Bi、Sb、Mo、Sn、Ag、Pb和Au等成矿元素,而且还强烈富集F、B和As等矿化剂元素,因此,碱长花岗斑岩是最有成矿远景的岩体。     

滇西腾冲地块高黎贡山群早志留世变质花岗岩体的年代学、地球化学特征及意义

西南特提斯构造带广泛发育的早古生代岩浆岩是冈瓦纳大陆边缘原特提斯洋增生造山作用的产物,目前报导的岩浆岩侵位时代在536~448Ma。本文通过LA-ICP-MS锆石U-Pb定年,在腾冲地块东缘高黎贡山群中首次发现了年轻至~437Ma的片麻状花岗质岩体,并结合其锆石Hf同位素和全岩主微量地球化学特征,进一步制约原特提斯洋构造演化过程。样品主量元素显示此片麻状花岗岩体具有高硅(SiO_2=72.78%~73.69%)、富碱(K_2O+Na_2O=7.23%~8.70%)的过铝质(A/CNK=1.08~1.12)特征,微量元素显示此岩体相对富集轻稀土元素、大离子亲石元素(K、Rb)和Pb,亏损高场强元素(Nb、Ta、P、Zr、Ti)以及Ba、Sr、Eu。综合岩石样品的矿物组合特征和地球化学特征,判断该岩体为S型花岗岩,源于以砂屑岩为主的沉积岩类的部分熔融,且源区有斜长石的残留。锆石εHf(t)值(-9.8~-6.2)和二阶段模式年龄tDM2(2.0~1.8Ga)也表明其源于古老地壳沉积物,且无幔源物质加入。根据全岩锆饱和温度计和锆石Ti温度计得出其岩浆从源区发生部分熔融到固结的过程中,温度从794℃左右下降到约754℃。熔浆温度较高,推测源区部分熔融过程中有地幔热的供给。综合前人研究成果,冈瓦纳大陆边缘在早古生代依次经历了原特提斯洋板片俯冲(ca.530~510Ma)、地块群增生与洋板片断离(ca.510~490Ma)、岩石圈挤压增厚(ca.490~475Ma)和岩石圈地幔拆沉(ca.470~460Ma)。岩石圈地幔拆沉将导致软流圈上涌及随后大陆岩石圈的持续伸展。腾冲地块侵位于~437Ma的花岗质岩体系该拆沉构造后的伸展环境中,以砂屑岩为主的古老地壳沉积岩在地幔热的供给下发生部分熔融的产物。     

Permian High Ba-Sr Granitoids: Geochemistry, Age and Tectonic Implications of Erlangshan Pluton, Urad Zhongqi, Inner Mongolia

Abstract: Erlangshan Pluton from Urad Zhongqi, central Inner Mongolia, is located in the middle segment of the northern margin of the North China Plate. The rocks consist mainly of diorites with gneissic structure. Petrochemical characteristics reveal that the diorites belong to metaluminous, high-potassium calc-alkaline series, with chemical signatures of I-type granites. They are characterized by low SiO2 contents (56.63%–58.53%) and A/CNK (0.90–0.96), high Al2O3 contents (17.30%–17.96%) and Na2O/K2O ratios (1.20–1.70), enrichment in large ion lithophile elements (LILE, e.g., Ba=556–915 ppm, Sr=463–595 ppm), and relative depletion in high field strength elements (HFSE, e.g., Nb, Ta, Ti) in primitive mantle-normalized spidergram, and right-declined rare earth element patterns with slightly negative Eu anomalies (d?Eu=0.72–0.90). They have Sr/Y ratios (20–25) evidently less than Kebu Pluton (49–75) to its east. Sensitive high resolution ion micro-probe U-Pb zircon dating of the diorites has yielded an intrusive age of 270±8?Ma. This leads us to conclude that Erlangshan diorites were formed by mixing between the middle or lower crustal-derived magma and minor mantle-derived mafic magma, followed by fractional crystallization, which was trigged by crustal extension and fault activity in post-collisional setting.     

华北花岗岩类的大地构造岩石化学特征

华北花岗岩类为酸性深成岩.以正长花岗岩和二长花岗岩为主,按照地洼学说的大地构造分类,它们分属于地槽、地台和地洼三个演化阶段,其岩石化学各具特征. 从地槽、地台至地洼阶段,华北花岗岩类具有明显的化学演化规律.例如,在化学成分方面表现为K_2O含量递增,而MgO和CaO含量递减;在岩石化学指数方面.表现为里特曼碱性指数、长英指数、钾质指数和碱度递增.而铝质指数,镁质指数和钠质指数则递减等等.     

阿尔泰造山带花岗岩时空演变、构造环境及地壳生长意义——以中国阿尔泰为例

阿尔泰造山带横跨中、俄、哈、蒙四国边界,是中亚造山带主要组成部分,发育大量的花岗岩等侵入体。本文研究总结这些岩体的时空演变、成因类型和构造环境,并探讨其增生造山和地壳生长意义。依据锆石年龄,这些岩体可大致分为早中古生代的470～440Ma(中晚奥陶世)和425～360Ma(晚志留世—晚泥盆世)、晚古生代的355～318Ma(早石炭世)和290～270Ma(早二叠世)以及早中生代245～190Ma(中晚三叠世—早侏罗世)3个阶段5个期次,其中425～360Ma花岗岩可进一步细分为425～390Ma和380～360Ma两个峰期。早中古生代(470～360Ma)花岗岩体分布广泛,主要为钙碱性I型,多具不同程度变形,其中470～440Ma岩体变形极强(片麻岩体)。它们为同造山俯冲增生产物,形成于活动陆缘俯冲(470～440Ma)、继续俯冲弧后盆地伸展(420～390Ma)到聚合碰撞(380～360Ma)的过程中。早石炭世岩体发育于造山带南部,为不变形圆形状或不规则状,具典型碱性花岗岩特征,为晚(后)造山产物。早二叠世岩体主要发育于阿尔泰造山带南部,少量分布于造山带内部,多为圆形,不变形,少量变形岩体集中在额尔齐斯构造带内,成因类型以I、A型为特点,伴生有大量基性岩脉(体),显示为后造山底侵伸展环境。早中生代岩体为不变形圆形或不规则状,具有高分异I型和S型花岗岩特征,伴有稀有金属矿产,具有板内环境特点。花岗岩体同位素填图显示,阿尔泰中部块体岩体具有较低的εNd(t)值和老的Nd同位素模式年龄(1～1.3Ga),暗示存在古老地壳基底;由北向南εNd(t)值增高,模式年龄变年轻,显示陆壳向南生长,其中水平和垂向生长率分别为18%～28%和7%～8%。中生代时期阿尔泰造山带保留水平增生结构,没有发生大规模构造块体垂向叠覆。阿尔泰造山带经历了古陆缘构造演化,奥陶纪—志留纪陆缘俯冲,泥盆纪陆弧及陆缘边缘裂解、弧后盆地形成,晚泥盆世最终洋盆闭合及早石炭世各块体拼合的演化过程。该研究表明增生造山带中同样存在构造演化的阶段性;中亚增生造山作用不仅具有弧前增生,而且还存在陆缘裂解再拼合作用。     

全吉地块金泉山—化石沟一带古生代 花岗质岩体地球化学及其构造意义

柴达木盆地北缘之全吉地块花岗质岩体大量发育,具多期次多阶段特征。通过对全吉地块金泉山—化石沟一带古生代花岗质岩体岩石学、岩石化学特征及单颗粒锆石U-Pb同位素定年,发现该区花岗岩有4次侵入,侵入时代分别为早奥陶世(471~476Ma)、中奥陶世(459±5Ma)、早志留世(423±4Ma)和中泥盆世(366±2Ma)。岩石地球化学研究显示,该4期花岗岩均具典型的钙碱性特征,轻稀土富集、重稀土轻度亏损、Eu轻微负异常—正异常,大离子亲石元素K2O、Rb、Ba、Th等相对强烈富集,高场强元素Nb、Ta、Hf、Zr及Yb明显亏损,除第4期岩体即具I型,又具S花岗岩特征外,其它各期次均属I型花岗岩,总体显示岩体具壳源特征,为板块碰撞前消减地区花岗岩,研究推测,金泉山—化石沟一带古生代花岗质岩体第1、2组年龄为全吉地块与柴达木陆块碰撞的时代,第3组年龄反映了深俯冲地下的板块由于拆沉而折返的时代,第4组年龄为碰撞隆起后造山带伸展、滑塌的时代。     

北疆及邻区石炭-二叠纪花岗岩时空分布特征及其构造意义

北疆及邻区发育大量的花岗岩,其中石炭-二叠纪花岗岩较为突出。本文总结了该期花岗岩的时空分布特征。北疆及邻区不同构造单元石炭-二叠纪花岗岩特征不同,形成时代峰期也不一致。在阿尔泰,该期花岗岩主要集中在早二叠世(289～266Ma),晚石炭世出现一个明显的岩浆宁静期;西准噶尔可以分为早石炭世(340～320Ma)和晚石炭世—早二叠世(310～290Ma)两期,后一期较强,铝质A型花岗岩分布广泛是该地区的一个重要特征,形成时代集中在300Ma左右;东准噶尔地区石炭-二叠纪花岗岩多沿断裂带展布,岩浆活动从晚石炭世一直延续到早二叠世(320～270Ma),该地区最大的特点是发育多条碱性(A型)花岗岩带,在晚石炭世—早二叠世连续产出。西天山大致可以分为3期:早石炭世(355～345Ma)、早石炭世晚期—晚石炭世(335～305Ma)和二叠纪(300～255Ma)。早石炭世花岗岩主要集中在北天山,早二叠世花岗岩浆活动最为强烈,其中的碱性(A型)花岗岩不仅在南天山呈带状大面积分布,在北天山也有发育;东天山—北山是区内石炭-二叠纪花岗岩最为发育的地区,岩体数量多,分布面积广,锆石年龄主要集中在335～310Ma和300～270Ma,相对来说来东天山石炭纪花岗岩较多,北山二叠纪花岗岩较多。总体而言,北疆及邻区石炭-二叠纪花岗岩时代主要集中在晚石炭世—早二叠世,特别是早二叠世,整体展现出同步性,这个时期碱性岩最发育,可能揭示了不同构造背景下的伸展特点。这是整个中亚造山带及邻区大量的酸性和基性-超基性岩浆活动及暗示的伸展环境的一个缩影。     

Early Paleozoic gabbro-granitoid associations in eastern segment of the Mongolian-Okhotsk foldbelt (Amur River basin): Age and tectonic position

Magmatic rocks of the Pikan and Un’ya massifs situated in eastern segment of the Mongolian-Okhotsk foldbelt are studied using isotopic-geochronological (U-Pb zircon dating) and geochemical methods. Two rock complexes different in age are recognized in the Pikan massif: the high-Al gabbro-tonalite association of the Middle Ordovician (468 ± Ma) and granodiorite-granite association of the Late Silurian-Early Devonian (415 ± 7 Ma). The Late Ordovician age (454 ± 5 Ma) is established for leucocratic granites of the Un’ya massif. As is suggested, the Pikan and Un’ya massifs are “allogenic blocks” detached from continental framework of the Mongolian-Okhotsk foldbelt and tectonically emplaced into the foldbelt structure at the last stage of its development.     

Granitoids of the Ufalei block (South Urals): Sr-Nd isotope systematics, geodynamic position and genetic reconstructions

Petrogeochemical and isotopic-geochronological signatures in granitoids developed in structures with complex geological history represent an important feature for reconstructing paleogeodynamic settings. Granitoids are widespread in the western slope of the Urals, where the Uralian Orogen contacts via a collage of different-age blocks of the east European Platform. The Ufalei block located in the Central Urals megazone at the junction between the South and Middle Urals’ segments represents one such boundary structure with multistage geological evolution. The isotopic ages obtained by different methods for acid igneous rocks range from 1290 to 245 Ma. We determined close Rb-Sr and Sm-Nd ages (317 Ma) for granites of the Nizhnii Ufalei Massif. By their petrochemical parameters, granitoids and host granite-gneisses differ principally from each other: the former are close to subduction-related, while the latter, to continental-riftogenic varieties. The primary ratio (⁸⁷Sr/8⁶Sr)₀ = 0.70428 and ?_Nd ≈ +4 values indicate significant contribution of oceanic (island-arc?) material to the substrate, which served as a source for granites of the Nizhnii Ufalei Massif. Model Nd ages of granites vary from 641 to 550 Ma. Distinct oceanic rocks and varieties with such ages are missing from the surrounding structures. New isotopic dates obtained for ultramafic and mafic rocks from different zones of the Urals related to the Cadomian cycle imply development of unexposed Upper Riphean-Vendian “oceanic” rocks in the central part of the Ufalei block, which played a substantial role in the formation of the Nizhnii Ufalei granitoids. Such rocks could be represented, for example, by fragments of the Precambrian Timanide-type ophiolite association. The analysis of original materials combined with published data point to the heterogeneous composition and structure of the Ufalei block and a significant part of the western segment of the Central Uralian Uplift and extremely complex geological history of the region coupling the Uralian Orogen with the East European Platform in the present-day structure.