洛南任家滩-荞麦山正长斑岩成因及其对古元古代晚期裂解的指示--岩石化学及锆石U-Pb年龄和Lu-Hf同位素特征

华北克拉通南缘的陕西洛南-河南豫西地区出露一系列形成于1.8~1.6Ga的碱性岩,对这些碱性岩的研究有助于提高对华北克拉通南缘古元古代构造环境的认识。本文选取陕西省洛南县任家滩-荞麦山一带碱性侵入体进行系统的岩石学、LA-ICP-MS锆石U-Pb年代学、Lu-Hf同位素分析和岩石地球化学研究,讨论了其成因机制和构造背景。研究表明,任家滩-荞麦山岩体的主体岩性为正长斑岩,加权平均年龄为1689±20Ma（MSWD=0.12）,表明其侵位时代为古元古代。该岩体富碱（Na2O+K2O=7.95% ~ 9.5%）,高钾（K2O=4.67% ~ 8.51%）;稀土元素总量较高（496.15×10-6 ~ 650.16×10-6,平均543.06×10-6）,轻、重稀土元素分馏比较明显,轻稀土元素相对富集（LREE=454×10-6 ~ 605×10-6）,重稀土元素亏损（HREE=39.3×10-6 ~ 45.6×10-6）,具有弱负铕异常;K、Rb、Ba、Th富集,Nb、Ta、P、Ti亏损,并且具有明显的Sr负异常。εHf（t）值<0,TDM1值为2038 ~ 2218Ma,TDM2值为2250 ~ 2516Ma,说明岩浆源区物质与富集地幔有关或受到过地壳物质的混染。因此,任家滩-荞麦山岩体是由地幔玄武质岩浆与地壳基底太华杂岩形成的中酸性花岗质岩浆混合后形成的熔体,经强烈的结晶分异作用形成的,其形成于陆内裂谷的构造环境,是华北克拉通南缘对哥伦比亚超大陆裂解事件的响应。     

华北克拉通辽东半岛新元古代早期基性岩浆活动:辉绿岩墙年代学和岩石地球化学证据

华北克拉通辽东半岛地区广泛发育侵位于青白口系不同层位中的辉绿岩(脉)岩墙,对其锆石CL图像、U--Pb定年和岩石地球化学特征研究得出以下结论。锆石类型有三组:前两组锆石具有早期岩浆作用的锆石属性或结晶基底的变质锆石属性,反映该区辉绿岩岩浆上升过程受到了陆壳的混染;第三组锆石多呈自形--半自形短柱状,发育岩浆振荡生长环带结构或条带结构,具原生岩浆成因锆石属性,锆石SHRIMP U--Pb定年显示其加权平均年龄为832.3±8.1 Ma(n=14,MSWD=1.3),可以代表辉绿岩的结晶年龄。岩石地球化学组成,其具有低Si O_2、Al_2O_3,高TFe_2O_3、MgO、Ti O_2的特征,这与拉斑玄武岩特征相似;其稀土元素总量相对较低(ΣREE=71.88×10~-6~129.64×10~-6),且具弱的正Eu异常和铌亏损;略富集轻稀土元素(LREE)、富集大离子亲石元素(LILE:Rb、Pb、Ba)和高场强元素(HFSE:Th、U、Zr、Ti、Hf),而亏损高场强元素(HFSE:Nb、Sm、Gd、P)等;以上特征指示岩浆源区为富集型地幔,且上侵位就位过程中受陆壳不同程度的同化混染。本文对辉绿岩的研究显示华北克拉通辽东半岛地区在新元古代早期存在基性岩浆活动,结合前人对华北克拉通中元古代晚期—新元古代早期构造--岩浆事件的研究成果,进一步证明了华北克拉通东北部在新元古代早期经历了挤压汇聚后的伸展裂解演化过程,这与Rodinia超大陆聚合和裂解事件一致。     

Upstairs-downstairs: supercontinents and large igneous provinces,are they related?

There is a correlation of global large igneous province (LIP) events with zircon age peaks at 2700, 2500, 2100, 1900, 1750, 1100, and 600 and also probably at 3450, 3000, 2000, and 300 Ma. Power spectral analyses of LIP event distributions suggest important periodicities at 250, 150, 100, 50, and 25 million years with weaker periodicities at 70–80, 45, and 18–20 Ma. The 25 million year periodicity is important only in the last 300 million years. Some LIP events are associated with granite-forming (zircon-producing) events and others are not, and LIP events at 1900 and 600 Ma correlate with peaks in craton collision frequency. LIP age peaks are associated with supercontinent rifting or breakup, but not dispersal, at 2450–2400, 2200, 1380, 1280, 800–750, and ≤200 Ma, and with supercontinent assembly at 1750 and 600 Ma. LIP peaks at 2700 and 2500 Ma and the valley between these peaks span the time of Neoarchaean supercraton assemblies. These observations are consistent with plume generation in the deep mantle operating independently of the supercontinent cycle and being controlled by lower-mantle and core-mantle boundary thermochemical dynamics. Two processes whereby plumes can impact continental assembly and breakup are (1) plumes may rise beneath supercontinents and initiate supercontinent breakup, and (2) plume ascent may increase the frequency of craton collisions and the rate of crustal growth by accelerating subduction.     

Continental growth and reworking on the edge of the Columbia and Rodinia supercontinents; 1.86–0.9 Ga accretionary orogeny in southwest Fennoscandia

Geological history from the late Palaeoproterozoic to early Neoproterozoic is dominated by the formation of the supercontinent Columbia, and its break-up and re-amalgamation into the next supercontinent, Rodinia. On a global scale, major orogenic events have been tied to the formation of either of these supercontinents, and records of extension are commonly linked to break-up events. Presented here is a synopsis of the geological evolution of southwest Fennoscandia during the ca. 1.9–0.9 Ga period. This region records a protracted history of continental growth and reworking in a long-lived accretionary orogen. Three major periods of continental growth are defined by the Transscandinavian Igneous Belt (1.86–1.66 Ga), Gothian (1.66–1.52 Ga), and Telemarkian (1.52–1.48 Ga) domains. The 1.47–1.38 Ga Hallandian–Danopolonian period featured reorganization of the subduction zone and over-riding plates, with limited evidence for continental collision. During the subsequent 1.38–1.15 Ga interval, the region is interpreted as being located inboard of a convergent margin that is not preserved today and hosted magmatism and sedimentation related to inboard extensional events. The 1.15–0.9 Ga period is host to Sveconorwegian orogenesis that marks the end of this long-lived accretionary orogen and features significant crustal deformation, metamorphism, and magmatism. Collision of an indenter, typically Amazonia, is commonly inferred for the cause of widespread Sveconorwegian orogenesis, but this remains inconclusive. An alternative is that orogenesis merely represents subduction, terrane accretion, crustal thickening, and burial and exhumation of continental crust, along an accretionary margin. During the Mesoproterozoic, southwest Fennoscandia was part of a much larger accretionary orogen that grew on the edge of the Columbia supercontinent and included Laurentia and Amazonia amongst other cratons. The chain of convergent margins along the western Pacific is the best analogue for this setting of Proterozoic crustal growth and tectonism.     

Nature of the Precambrian metamorphic blocks in the eastern segment of Central Tianshan: Constraint from geochronology and Nd isotopic geochemistry

The Central Tianshan Tectonic Zone (CTTZ) is anarrow domain between an early Paleozoic southernTianshan passive continental margin and a late Paleo-zoic northern Tianshan arc zone, which is character-ized by the presence of numerous Precambrian meta-morphic basement blocks. Proterozoic granitoidgneisses and metamorphic sedimentary rocks,namely Xingxingxia and Kawabulag and Tianhugroups, are the most important lithological assem-blages in these metamorphic basement blocks, and alittle of …     

中国东南极地质考察20年进展与展望

在1998—2017年期间,我国组织了14次东南极地质考察,将考察的范围从中山站所在的拉斯曼丘陵向外扩展了约400 km,主要包括格罗夫山、埃默里冰架东缘-西南普里兹湾、北查尔斯王子山、布朗山、赖于尔群岛和西福尔丘陵等露岩区。通过大、中比例尺的地质编图和多学科综合研究,取得如下重要进展:(1)确定格罗夫山冰下高地为泛非期(~570—500 Ma)单相变质地体,发现镁铁质和泥质高压麻粒岩并刻画了泛非期造山的精细过程,为普里兹造山带的碰撞造山成因以及冈瓦纳超大陆的多陆块汇聚模型提供了岩石学支撑;(2)论证在印度克拉通与东南极陆块之间存在一个延长2 000 km的中元古代长寿命大陆岛弧,岛弧岩浆作用从~1 500 Ma一直持续到~1 000 Ma,提出雷纳造山带格林维尔期(~1 000—900 Ma)的构造演化可能经历了从弧陆碰撞到陆陆碰撞的过程;(3)在赖于尔群岛超高温变泥质岩中识别出早期蓝晶石的残留,确定了超高温变质作用顺时针演化的精细P-T轨迹;(4)在西福尔丘陵西南部基性岩墙群中发现了格林维尔期(~960—940 Ma)不均匀麻粒岩化,变质条件达820—870℃、0.84—0.97 GPa,认为西福尔陆块也卷入到印度克拉通与东南极陆块的碰撞造山过程;(5)在西福尔丘陵东南部浅变质冰川漂砾和松散砂中获得~3.5—3.3 Ga的古老锆石U-Pb年龄,推测在西福尔丘陵东南方向存在一个从前未知的古太古代冰下陆块。建议今后在东南极面向印度洋构造域的地质考察要进一步扩展到南查尔斯王子山、内皮尔杂岩和登曼冰川,研究工作的重点仍聚焦在南极大陆如何响应地质历史时期里超级大陆的聚散过程这一关键科学问题上,并可在以下几个方面展开:(1)太古宙古老地壳及陆核的识别与全球对比;(2)格林维尔期造山记录与罗迪尼亚超大陆汇聚;(3)泛非期造山记录与冈瓦纳超大陆汇聚;(4)显生宙冈瓦纳超大陆裂解及陆块分离。通过这些考察和研究工作,可以促使我国对南极地质科学的研究达到国际先进水平。     

试论中国古大陆中-新元古代汇聚与裂解的地质记录

自1990年新元古Rodinia超大陆提出后,现已发展成地学研究热点之一。在全球新元古代超大陆旋回的汇聚与裂解机制影响下,中国古大陆也随之变化。中元古代末一新元古代初的汇聚和新元古代晚期的裂解是最重要的两次地质事件。塔里木、华北、华南古陆都有它的地质记录。晋宁事件应是中元古代晚期-新元古代早期,北秦岭地块与中秦岭地块俯冲一碰撞造山作用和新元古代时期Rodinia超大陆形成的主要地质事件;华南的武陵运动,使华夏古陆与扬子地块发生碰撞形成统一的“华南古陆”。在塔里木古陆与哈萨克斯坦一伊犁古陆之间的那拉提南缘碰撞带,甘肃北山南带柳园及青海柴达木盆地北部边缘的榴辉岩一花岗岩带的发现都是最新的研究成果。     

扬子陆块~2.0 Ga的区域变质事件对南北黄陵古元古代差异演化的启示

扬子陆核黄陵地区发育较为完整的太古宙—古元古代片麻岩、表壳岩组合(即崆岭杂岩),前人调查研究认为南北黄陵Ar-Pt1具有一致的物质组成和地质演化过程。笔者分别对南北黄陵太古宙花岗质片麻岩进行锆石年代学研究发现,北黄陵2件样品(HL013-1、HL013-2)均存在大量锆石发育岩浆核-变质边结构,都获得～2.8 Ga原岩结晶年龄和～2.0 Ga变质年龄;而南黄陵1件样品(HL005-3)以具振荡环带结构的岩浆锆石为主,仅获得～2.9 Ga原岩结晶年龄。结合前人研究成果发现,～2.0 Ga的变质年龄在北黄陵太古宙—古元古代的花岗片麻岩、表壳岩中广泛发育,而在南黄陵相似建造中均未获得,一定程度上说明北黄陵地区广泛遭受～2.0 Ga的区域变质作用而南黄陵不发育,南北黄陵在古元古代可能处在不同地块或者同一地块不同部位。2.1～1.6 Ga的构造岩浆事件的分布特点说明扬子陆块可能存在多条古元古代造山带,扬子陆块古元古代以多块体拼贴为特点,广泛记录2.1～1.6 Ga的构造岩浆事件说明扬子陆块是全球哥伦比亚超大陆的重要组成部分。     

桂北地区丹洲群碎屑锆石LA-ICP-MS U-Pb年龄和Hf同位素特征及其地质意义

桂北丹洲群顶部拱洞组粉砂岩的碎屑锆石的阴极发光图像和Th/U(0.2~2.4)值显示,它们均为岩浆成因的锆石。锆石~(206)Pb/~(238)Pb年龄分布在730~769Ma和771~850Ma之间,这些锆石的Hf同位素成分范围较大,ε_(Hf)(t)值和二阶段Hf模式年龄(T_(DM2))分别为-18.4~11.4和1020~2812Ma。此外,样品中还有一些年龄较老的锆石颗粒,~(207)Pb/~(206)Pb年龄为1910~3140Ma,ε_(Hf)(t)值和二阶段Hf模式年龄(T_(DM2))分别为-13.6~3.4和2740~3635Ma。结合前人的研究推测,桂北丹洲群拱洞组沉积年龄小于等于706±10Ma,物源主要由扬子板块新元古代岩浆岩组成,也有少量太古宙岩浆岩的加入。推测中国华南地区存在对应于Rodinia超大陆聚合相关的格林威尔运动的响应。根据已测锆石的ε_(Hf)(t)值和Hf二阶段模式年龄推断,研究区地壳生长主要经历3个阶段:(1)3.64~3.25Ga,初生地壳出现在3.64Ga;(2)2.98~2.37Ga;(3)2.19~1.28Ga,地壳生长的主要时期。     

阿尔金南缘新元古代盖里克片麻岩年代学、地球化学特征及其构造意义

盖里克片麻岩分布于阿中地块亚干布阳-帕夏拉依档一带,岩体主要岩性由眼球状黑云斜长片麻岩、二云二长片麻岩组成。LA-ICP-MS锆石U-Pb定年得到²⁰⁶Pb/²³⁸U加权平均年龄值为(886.5±5)Ma,说明盖里克片麻岩原岩形成于新元古代早期青白口纪;地球化学结果显示：主量元素具有高SiO₂、Al₂O₃、K₂O+Na₂O含量,低Na₂O、MgO、CaO和TiO₂含量的特征,A/CNK值介于1.03~1.17之间,属于高钾钙碱性系列的过铝质花岗岩。岩石富集Rb、Th、K等大离子亲石元素,亏损Nb、Ta、Sr、P、Hf、Ti等高场强元素,具有典型的大陆碰撞型花岗岩相应的元素丰度特征;岩石轻稀土富集而重稀土亏损,具有明显的负Eu异常,总体呈右倾的“V”型稀土分配模式,显示了典型的地壳重熔型花岗岩特征。盖里克片麻岩的源岩为地壳中角闪岩相基性岩类(变玄武岩),形成于同碰撞构造环境。综上说明本区存在新元古代早期的构造岩浆事件,可能对应于新元古代的罗迪尼亚(Rodinia)超大陆汇聚事件,说明塔里木和柴达木板块之间在新元古代早期曾经存在板块的汇聚碰撞。