川东北地区中侏罗世新田沟期古气候波动的地球化学响应

四川盆地中侏罗统新田沟组作为侏罗纪大面积红层之下的重要岩石地层单元,见证了盆地由潮湿向干旱转变的整个过程。然而,以往的研究主要集中在古气候类型方面,缺乏系统深入的气候变化研究。本文以川东北地区宣汉七里乡塔坝剖面为对象,系统分析了泥岩的主微量元素地球化学特征,结果表明:化学蚀变指数(CIA)、C值、Sr/Cu、Sr/Ba、Rb/Ti、Cs/Ti、Rb/K等7种古气候替代指标综合显示新田沟期气候存在从炎热潮湿逐渐向干旱转变的趋势,整体以半干旱-半潮湿气候为主。且该时期气候变化过程并不稳定,存在多个短期的湿热与干旱的气候波动。在新田沟组沉积末期,气候条件变得极端干燥。川东北地区中侏罗世的元素地球化学特征记录了区域内重大地质转折期将至时的气候变化,在侏罗纪大面积红层发生之前,气候条件已经开始响应。在中侏罗世早期,四川盆地与欧洲地区并不处于同一个气候带内。     

广元恐龙化石埋藏地沙溪庙组地球化学特征及对物源区和古风化作用的指示

广元恐龙化石埋藏地是四川盆地中侏罗世重要的恐龙化石点,恐龙化石埋藏于中侏罗统沙溪庙组之中。笔者对该恐龙化石埋藏地沙溪庙组泥质岩的常量元素、微量元素和稀土元素特征进行了研究,并根据泥质岩的地球化学特征讨论了物源区性质、构造背景以及物源区的风化特征。主量元素和稀土元素表明其物源区以长英质岩石为主,构造背景为被动大陆边缘:指示化学风化程度的CIA指数及成分成熟度的ICV指数,表明物源区经历了中等的化学风化作用,反映了中侏罗世恐龙生活在半干旱的古气候环境之中。     

四川盆地中生代古气候变化:来自深时古土壤证据

定量的古气候重建可为当前及未来可能的气候/环境变化提供基础性参考。发育自四川盆地中生代地层的古土壤蕴藏了丰富的陆相古气候信息,利用古土壤的地球化学指数、钙质古土壤成壤碳酸盐结核深度及其氧同位素组成与年均降水量、温度之间的关系,定量重建四川盆地中生代（晚三叠世晚期—白垩纪）年均降水量与温度的变化。结果表明:四川盆地中生代年均降水量变化较大,为145~1 400 mm;年均温度变化幅度相对较小,为7 °C~15 °C;总体上属于温带干旱—湿润交替的气候环境但以温带半干旱、干旱气候为主。其中晚三叠世晚期年均降水量为1 180~1 400 mm,年均温度为9 °C~15 °C,侏罗纪年均降水量为150~1 140 mm,年均温度为7 °C~15 °C,早白垩世早期与晚白垩世晚期的年均降水量与温度分别为150~720 mm、8 °C~12 °C和150~575 mm、10 °C~11 °C。区域陆相气候变化原因分析显示,波动的气候一方面与东亚季风环流、行星环流、区域构造运动导致的盆地内部山系隆起及古地理格局引起的焚风效应有关,另一方面还与区域构造运动引起海岸山脉裂解有关。     

漠河盆地中侏罗统砂岩地球化学特征及物源属性分析

漠河盆地的中侏罗统.砂岩具有高SiO2、低Fe2O3、FeO 、MgO 和轻稀土元素富集, 重稀土相对亏损,显示弱的负Eu异常的特征.综合分析砂岩的常量元素、微量元素和稀土元素的地球化学特征,经构造判别图解,笔者认为漠河盆地中侏罗统沉积时物源区具有大陆岛弧和活动大陆边缘的构造环境.盆地南侧的额尔古纳地块北缘古生代杂岩可能是盆地的主要物源.     

Detrital zircon U–Pb ages of Late Triassic–Late Jurassic deposits in the western and northern Sichuan Basin margin: constraints on the foreland basin provenance and tectonic implications

Upper Triassic to Upper Jurassic strata in the western and northern Sichuan Basin were deposited in a synorogenic foreland basin. Ion–microprobe U–Pb analysis of 364 detrital zircon grains from five Late Triassic to Late Jurassic sandstone samples in the northern Sichuan Basin and several published Middle Triassic to Middle Jurassic samples in the eastern Songpan–Ganzi Complex and western and inner Sichuan Basin provide an initial framework for understanding the Late Triassic to Late Jurassic provenance of western and northern Sichuan Basin. For further understanding, the paleogeographic setting of these areas and neighboring hinterlands was constructed. Combined with analysis of depocenter migration, thermochronology and detrital zircon provenance, the western and northern Sichuan Basin is displayed as a transferred foreland basin from Late Triassic to Late Jurassic. The Upper Triassic Xujiahe depocenter was located at the front of the Longmen Shan belt, and sediments in the western Sichuan Basin shared the same provenances with the Middle–Upper Triassic in the Songpan–Ganzi Complex, whereas the South Qinling fed the northern Sichuan Basin. The synorogenic depocenter transferred to the front of Micang Shan during the early Middle Jurassic and at the front of the Daba Shan during the middle–late Middle Jurassic. Zircons of the Middle Jurassic were sourced from the North Qinling, South Qinling and northern Yangtze Craton. The depocenter returned to the front of the Micang Shan again during the Late Jurassic, and the South Qinling and northern Yangtze Craton was the main provenance. The detrital zircon U–Pb ages imply that the South and North China collision was probably not finished at the Late Jurassic.     

柴达木盆地侏罗纪古气候演变过程: 来自化学风化特征的证据

柴达木盆地侏罗系陆相地层记录了该时期一系列重大的构造-气候-环境耦合演化事件,然而针对该套地层的古气 候、古风化作用等方面研究还很薄弱。为了恢复柴达木盆地侏罗纪时期的古气候和古环境特征,文章研究对柴北缘大煤沟侏 罗系标准剖面的沉积岩样品开展了全岩主、微量元素测试,综合采用多种化学风化指数判定柴达木盆地侏罗纪古气候条件及 演变过程。元素比值(Rb/Sr、K/Na、Na/Al 和Na/Ti)和化学风化指数(CIA、CIW、PIA 和ICV)均显示,柴达木盆地侏罗纪化学风 化过程和古气候演化过程可划分为4 个阶段：早侏罗世早-中期和中侏罗世中期,化学风化作用强烈,古气候处于温带-亚热 带温暖、潮湿气候条件;早侏罗世晚期和中侏罗世晚期-晚侏罗世,受到区域降水减少影响,盆地化学风化作用显著减弱,整体 处于干旱、半干旱环境。以上结果与前人基于沉积物和植物群面貌研究得出的古气候变化过程相吻合,为盆地及区域陆相侏 罗纪古气候研究提供了相对完整而连续的地球化学证据和参考。     

柴达木盆地侏罗纪古气候演变过程：来自化学风化特征的证据

柴达木盆地侏罗系陆相地层记录了该时期一系列重大的构造—气候—环境耦合演化事件，然而针对该套地层的古气 候、古风化作用等方面研究还很薄弱。为了恢复柴达木盆地侏罗纪时期的古气候和古环境特征，文章研究对柴北缘大煤沟侏 罗系标准剖面的沉积岩样品开展了全岩主、微量元素测试，综合采用多种化学风化指数判定柴达木盆地侏罗纪古气候条件及 演变过程。元素比值(Rb/Sr、K/Na、Na/Al 和Na/Ti)和化学风化指数(CIA、CIW、PIA 和ICV)均显示，柴达木盆地侏罗纪化学风 化过程和古气候演化过程可划分为4 个阶段：早侏罗世早—中期和中侏罗世中期，化学风化作用强烈，古气候处于温带—亚热 带温暖、潮湿气候条件；早侏罗世晚期和中侏罗世晚期—晚侏罗世，受到区域降水减少影响，盆地化学风化作用显著减弱，整体 处于干旱、半干旱环境。以上结果与前人基于沉积物和植物群面貌研究得出的古气候变化过程相吻合，为盆地及区域陆相侏 罗纪古气候研究提供了相对完整而连续的地球化学证据和参考。     

延边天宝山多金属矿田辉钼矿Re-Os同位素 年龄及其地质意义

延边天宝山为一大型中高温热液多金属(铅,锌,铜,钼等)矿田,是由新兴铅锌、立山铅锌铜和东风铅锌铜钼3个矿床所组成.文章在矿田地质特征研究的基础上,进行了辉钼矿Re-Os同位素体系定年研究,得到结果w(Re)为0.353～9.306 μg/g,模式年龄为174.7～200.3 Ma,加权平均值年龄为(194.6±3.9) Ma,等时线年龄为(196.6±2.5) Ma(MSWD=0.94,n=9),表明天宝山多金属矿田为早侏罗世岩浆作用及相关流体活动的产物,形成于华北板块和西伯利亚板块碰撞拼合后伸展环境,初步认为成矿物质来源主要为壳源.结合区域上已有的高精度年代学数据,将吉林省中东部山区钼成矿作用划分为2期:早侏罗世(196.6～186Ma)和中侏罗世(176.9～166.9Ma),且以中侏罗世钼矿化最为发育.     

Tectonic and Environmental Evolutions of the Northern Tibetan Plateau Prior to the Collision of India with Asia

Tectonic and environmental patterns and evolution of the present North Tibetan Plateau(NTP) prior to the India collision with Asia is significant to understand the formation of the Tibetan Plateau and its influence on the environment. In this study, we integrated and analyzed the tectonostratigraphy and the special sedimentary layers whose climatic implications are clear in the NTP. Additionally, we stressed the tectonic and environmental events and their evolutions from the Mesozoic to the Early Cenozoic. Our results show that four tectonic phases, which sequentially took place during the Triassic, Jurassic, Cretaceous and Paleogene, played an important role on the formation of the North Tibet. The climate was basically dry and hot from the Triassic to the Eocene and became dry and cool since the Oligocene in this region. The climatic evolution was characterized by a transition from a wet and hot phase during the Triassic- Middle Jurassic, to a dry and hot phase during the Late Jurassic- Eocene. Both phases encompassed 5 wet and hot periods followed by 5 dry and hot climate events, respectively. In addition, we found that the tectonic deformation and the climatic conditions were spatially and temporally different. In detail, in the regions north of the PaleoTian Shan and Paleo-Qilian Mts. the tectonic deformation and climatic condition were stronger and wetter than in regions south of the Paleo-Tian Shan and Paleo-Qilian Mts. during the Late Triassic – Jurassic. Whereas in the Cretaceous, the tectonic movement was intensive in the west but steady in the east, and climate was dry in the south but wet in the north of NTP. The formation of the tectonic and climatic patterns in NTP were the consequence of either global climate change or regional tectonics, including the Paleo-Asian Ocean closure and the Qiangtang block, Lhasa block and India plate collision subsequently to Asia. Furthermore, the regional tectonic events occurred before any global climate change and drove the climatic change in the NTP.     

地球化学记录揭示的柴达木盆地北缘地区中—晚侏罗世古环境与古气候*

沉积岩的地球化学特征是古环境变化良好的示踪剂,柴达木盆地北缘地区侏罗系记录了中国西北地区古环境、古气候演化的重要信息。本研究通过对柴达木盆地北缘地区大煤沟侏罗系标准剖面沉积岩的元素地球化学分析,尝试恢复了研究区中—晚侏罗世的古环境特征。结果显示:(1)研究区中—晚侏罗世以富氧的浅水环境为主,仅在短期内出现较深湖相沉积;整体上侏罗纪湖盆水体盐度较低,而部分层段沉积物盐度增大系降雨量相对减小导致。(2)基于多元地球化学参数建立的古气候演化曲线表明,中—晚侏罗世柴达木盆地北缘地区古气温、古湿度均在一定幅度内频繁变化;自中侏罗世晚期开始,研究区古气候开始由温暖潮湿向炎热干旱转变,至晚侏罗世进入了干热环境主导的阶段。多元地球化学参数剖面的建立为中国西北地区中—晚侏罗世“干热化事件”和区域古气候的研究对比提供了新的证据和材料。     

Lower Cretaceous paleosols and paleoclimate in Sichuan Basin,China

Abundant Lower Cretaceous (Berriasian–Hauterivian) paleosols have been recognized in the Sichuan Basin, along with the preserved pedogenetic features, e.g., soil horizons, soil structure, root traces and pedogenic nodules. Chemical, geochemical and mineralogical analyses were used to examine the paleosols. These paleosols were classified as Entisols, Inceptisols, Aridisols and Alfisols in terms of the modern soil taxonomic system. Early Cretaceous paleoprecipitation and paleotemperature in the Sichuan Basin were estimated from the degree of chemical weathering for non-calcareous paleosols, and from the depth to the calcic horizon and stable oxygen isotopic composition of pedogenic carbonates in calcareous paleosols, respectively. A temperate semi-arid climate generally prevailed in the Sichuan Basin as a part of the South China Block (SCB) and was controlled by subtropical high-pressure and a rain-shadow effect because the humid air masses from the Paleo-Pacific were impeded by the highlands of the South China Block. Further, several intervals of sub-humid paleoclimate occurred due to strengthened monsoonal circulation in the Early Cretaceous. Using the paleosol barometer, the paleoatmospheric CO₂ levels of the Early Cretaceous are estimated to range from ∼120 to ∼520 ppmv, with a mean of 305 ppmv. Regional temperature is generally coupled with atmospheric CO₂ concentration and is roughly consistent with the sea level fluctuation.     

古土壤:沉积环境和古气候变化的灵敏指针

古土壤是古代沉积环境和气候变化的灵敏记录者,可以为深刻认识地球演化历史中的重要地质事件提供有效信息,并成为当前沉积学领域的研究热点之一。国外古土壤研究已经涉及到太古代以来的几乎所有沉积地层,而国内古土壤的研究仍以第四纪地层为主,对前第四纪漫长地质时期地层记录中的古土壤研究较少。基于古土壤的识别特征及其埋藏后发生的可能变化,分析了古土壤在沉积环境解释和地层划分对比中的作用。其中,古土壤钙积层发育深度、元素地球化学、成土碳酸盐岩稳定同位素等对于合理评价成土作用过程、划分成土相及定量恢复古气候（年均降水量、年均气温和pCO₂）等方面的研究发展迅速,不同估算古气候参数的经验公式都有明显的适用性特点。近年来,国内学者对松辽、四川、胶莱盆地等的白垩系古土壤进行了很多调查研究,并取得了较好的研究成果。而包括江西、广东、浙江等在内的中国东南地区白垩系陆相红层研究结果显示,这些地层含有丰富的古土壤,总体为地表干旱氧化条件下形成的红色古土壤序列。通过对国际古土壤研究动态的综述,以期引起国内更多沉积学工作者关注前第四纪地层记录中的古土壤,为更好地认识古代地球环境变化做出更大贡献。     

晚侏罗世东亚多向汇聚构造体系的形成与变形特征

板块构造研究成果与同位素精确定年数据的积累,使我们对发生在中国东部的晚侏罗世-早白垩世东亚多向汇聚作用有了深刻的认识.全球三大洋在晚侏罗世(165±5)Ma近乎同时的开启,以及东亚周边占太平洋、新特提斯洋和蒙古-鄂霍茨克洋的俯冲消亡,在中国中东部和东亚地区形成了多向挤压汇聚的燕山期构造体系,即东业多向汇聚构造体系(简称东亚汇聚).东亚汇聚启动了经典的燕山运动,发育了独特的构造变形特征.东亚汇聚构造体系具有两个近乎稳定的刚性陆核,即鄂尔多斯地块和四川(盆地)地块,在它们的周缘形成了晚侏罗世-早白垩世陆内多向挤压变形和似前陆盆地,如大巴山晚侏罗世前陆.此外,东亚多向汇聚构造体系影响了东亚和中亚大部分地区的板内变形作用,在中国大陆及其周边形成了反映南北向挤压的蒙古弧共轭走滑断裂系统、燕山-阴山陆内造山带、大别山-大巴山侏罗纪陆内造山带等典型的燕山期构造带.东亚汇聚具有深刻的全球构造背景与动力来源,是重要的科学研究问题.     

Geology,geochronology and geochemistry of large Duobaoshan Cu-Mo-Au orefield in NE China: Magma genesis and regional tectonic implications

Duobaoshan is the largest porphyry-related Cu-Mo-Au orefield in northeastern(NE)Asia,and hosts a number of large-medium porphyry Cu(PCDs),epithermal Au and Fe-Cu skarn deposits.Formation ages of these deposits,from the oldest(Ordovician)to youngest(Jurassic),have spanned across over 300 Ma.No similar orefields of such size and geological complexity are found in NE Asia,which reflects its metallogenic uniqueness in forming and preserving porphyry-related deposits.In this study,we explore the actual number and timing of magmatic/mineralization phases,their respective magma genesis,fertility,and regional tectonic connection,together with the preservation of PCDs.We present new data on the magmatic/mineralization ages(LA-ICP-MS zircon U-Pb,pyrite and molybdenite Re-Os dating),whole-rock geochemistry,and zircon trace element compositions on four representative deposits in the Duobaoshan orefield,i.e.,Duobaoshan PCD,Tongshan PCD,Sankuanggou Fe-Cu skarn,and Zhengguang epithermal Au deposits,and compiled published ones from these and other mineral occurrences in the orefield.In terms of geochronology,we have newly summarized seven magmatic phases in the orefield:(1)Middle-Late Cambrian(506-491 Ma),(2)Early and Middle Ordovician(485-471 Ma and~462 Ma),(3)Late Ordovician(450-447 Ma),(4)Early Carboniferous and Late-Carboniferous to Early Permian(351-345 and 323-291 Ma),(5)Middle-Late Triassic(244-223 Ma),(6)Early-Middle and Late Jurassic(178-168 Ma and~150 Ma),and(7)Early Cretaceous(~112 Ma).Three of these seven major magmatic phases were coeval with ore formation,including(1)Early Ordovician(485-473 Ma)porphyry-type Cu-Mo-(Au),(2)Early-Middle Triassic(246-229 Ma)porphyry-related epithermal Au-(Cu-Mo),and(3)Early Jurassic(177-173 Ma)Fe-Cu skarn mineralization.Some deposits in the orefield,notably Tongshan and Zhengguang,were likely formed by more than one mineralization events.In terms of geochemistry,ore-causative granitoids in the orefield exhibit adakite-like or adakite-normal arc transitional signatures,but those forming the porphyry-/epithermal-type Cu-Mo-Au mineralization are largely confined to the former.The varying but high Sr/Y,Sm/Yb and La/Yb ratios suggest that the ore-forming magmas were mainly crustal sourced and formed at different depths(clinopyroxene-/amphibole-/garnet-stability fields).The adakite-like suites may have formed by partial melting of the thickened lower crust at 35-40 km(for the Early Ordovician arc)and>40 km(for the Middle-Late Triassic arc)depths.The Early Jurassic Fe-Cu skarn orecausative granitoids show an adakitic-normal arc transitional geochemical affinity.These granitoids were likely formed by partial melting of the juvenile lower crust(35-40 km depth),and subsequently modified by assimilation and fractional crystallization(AFC)processes.In light of the geological,geochronological and geochemical information,we proposed the following tectonometallogenic model for the Duobaoshan orefield.The Ordovician Duobaoshan may have been in a continental arc setting during the subduction of the Paleo-Asian Ocean,and formed the porphyry-related deposits at Duobaoshan,Tongshan and Zhengguang.Subduction may have ceased in the latest Ordovician,and the regional tectonics passed into long subsidence and extension till the latest Carboniferous.This extensional tectonic regime and the Silurian terrestrial-shallow marine sedimentation had likely buried and preserved the Ordovician Duobaoshan magmatic-hydrothermal system.The south-dipping Mongol-Okhotsk Ocean subduction from north of the orefield had generated the Middle-Late Triassic continental arc magmatism and the associated Tongshan PCD and Zhengguang epithermal Au mineralization(which superimposed on the Ordovician PCD system).The Middle Jurassic closure of Mongol-Okhotsk Ocean in the northwestern Amuria block(Erguna terrane),and the accompanying Siberia-Amuria collision,may have placed the Paleo-Pacific subduction system in NE China(including the orefield)under compression,and formed the granodiorite-tonalite and Fe-Cu skarn deposits at Sankuanggou and Xiaoduobaoshan.From the Middle Jurassic,the consecutive accretion of Paleo-Pacific arc terranes(e.g.,Sikhote-Alin and Nadanhada)onto the NE Asian continental margin may have gradually distant the Duobaoshan orefield from the subduction front,and consequently arc-type magmatism and the related mineralization faded.The minor Late Jurassic and Cretaceous unmineralized magmatism in the orefield may have triggered mainly by the far-field extension led by the post-collisional(Siberia-Amuria)gravitational collapse and/or Paleo-Pacific backarc-basin opening.     

Late Ordovician to early Silurian calc-alkaline magmatism in the Xiemisitai Mountains,northern West Junggar: a response to the subduction of the Junggar-Balkhash Ocean

Basement exposed in the Placer de Guadalupe–Plomosas uplift in northern Mexico provides important clues for the geologic evolution of the region. The stratigraphic units form stacked thrust sheets of psammitic and calcareous formations, interlayered with magmatic rock. The eastern calcareous and quartzite formations exhibit structures associated with ductile deformation, whereas the upper stratigraphic units only contain structures formed via younger brittle deformation. Porphyry interlayered in the upper Plomosas Formation has a U-Pb zircon age of 171 ± 1 Ma. This age is consistent with its stratigraphic position, interbedded quartzarenites with a maximum depositional age of ~168 Ma. Granite flakes within the Horquilla Formation are dated at 209 ± 3 Ma, and the La Viñata quartzite exhibits a maximum age of ~193 Ma. The Upper Plomosas Formation correlates well with the arc-related Middle Jurassic Nazas Formation of northeastern Mexico, constituting the first report of a Jurassic continental margin arc outcrop in the ‘Central Mexican Gap zone’. We document Late Norian to Bajocian ages for the stratigraphic units cropping out in the Placer de Guadalupe area. The Jurassic age cluster indicates that the Nazas Arc magmatism in the region occurred during the Late Triassic and ended in the Middle Jurassic times. Permian ages previously assigned to these rocks and the occurrence of a Permo–Triassic deformation event have to be dismissed.     

塔里木盆地喀什凹陷侏罗系沉积特征及其演化

野外地质调查和室内地震解释认为,喀什凹陷侏罗系为陆相河流—湖泊沉积,整个侏罗纪代表了一个水体由浅—深—浅的沉积演化,早侏罗世莎里塔什组属干燥、氧化环境中的冲积扇沉积,到康苏组时演化为潮湿气候条件下的辫状河流沉积;中侏罗世盆地沉积范围扩大,出现湖泊和扇三角洲沉积,晚侏罗世盆地又演化为干燥—半干燥环境下的河流与冲积扇沉积。     

川东北地区通南巴背斜中三叠世以来构造变形时间厘定及其地质意义

通南巴背斜位于四川盆地东北部,中三叠世以来经历多期构造挤压与叠加作用,其形成与演化主要受到米仓山构造带由北西向南东冲断挤压作用的控制以及大巴山构造带由北东向南西构造叠加的影响,因此,厘定通南巴背斜的构造活动时间可以有效约束米仓山中三叠世以来陆内变形时间,亦对区域构造变形时序以及米仓山基底冲断变形特征有指示意义。本文以两条地质剖面为基础,刻画出背斜南翼中-上侏罗统旋转生长地层特征,表明地层发生褶皱的启动时间为中侏罗世晚期-晚侏罗世早期,并且通过长剖面解释,认为米仓山基底发育楔入冲断构造,楔端点位移沿前震旦系滑脱层向盆地扩展传递导致了通南巴背斜NE向构造的形成。磷灰石裂变径迹热模拟显示,通南巴背斜分别于晚白垩世早期(95~90 Ma)和新生代中晚期(~24 Ma)开始快速隆升剥蚀,隆升速率分别为0.06~0.085 mm/a和0.133 mm/a左右。通过汇总区域低温热年代学样品点,分区建立构造变形时空序列,得出川东北地区在中-晚侏罗世、白垩纪以及始新世-中新世分别发生一次米仓山由北向南的构造扩展以及大巴山由北东向南西的构造叠加作用。     

西藏羌塘中部亚丹高压变质岩年代学、地球化学特征及其构造意义

羌南和羌北地块沿龙木错-双湖缝合带碰撞对接,标志着古特提斯洋的最终闭合,然而古特提斯洋的构造演化,尤其它的打开时限一直争议不断。本文对龙木错-双湖缝合带以南荣玛地区的变质杂岩进行了岩相学、年代学和地球化学特征研究,进而约束古特提斯洋的开、合时限及其关闭后的构造演化特征。通过LA-ICP-MS锆石U-Pb定年,本文首次报道了1件新元古代斜长角闪岩,其加权平均年龄为717±7Ma(n=61,MSWD=1. 9),表明原岩形成于新元古代中期,反映羌南地区存在前寒武基底;另获得1件中侏罗世斜长角闪岩的锆石加权平均年龄为163±2Ma(n=26,MSWD=1. 9),表明其原岩形成于中侏罗世;获得2件石榴石多硅白云母石英片岩锆石边部谐和年龄范围分别为267～1349Ma和214～2050Ma;另对片岩中2组多硅白云母样品进行~(40)Ar/~(39)Ar定年,分别获得224. 2±1. 5Ma和223. 9±1. 5Ma的一致坪年龄,暗示区域变质作用可能从～224Ma持续到214Ma之后,且～214Ma的岩浆事件可能形成于碰撞过程中。新元古代和中侏罗世斜长角闪岩的岩石地球化学特征显示,前者原岩具E-MORB特征,后者原岩趋向于OIB特征。基于区域岩石组合与地球化学特征,推断二者均形成于伸展环境,前者可能形成于陆内伸展背景,响应Rodinia超大陆的裂解,后者可能形成于大陆裂谷环境,响应羌南、羌北地块碰撞结束后的裂解。综合前人与本文研究成果,认为新元古代中期(～717Ma),某未知陆块可能就已逐渐开始从羌南-印度大陆裂解,导致"古特提斯洋"在ca. 717～517Ma之间的某个时间点就已打开;古特提斯洋可能在～224Ma才完成闭合,羌南、羌北陆陆碰撞挤压持续到214Ma之后;中侏罗世区域为裂谷伸展环境,并发育OIB特征的碱性玄武岩和双峰式火成岩。     

内蒙古科尔沁右翼中旗花岗斑岩年代学研究

对内蒙古科尔沁右翼中旗花岗斑岩的同位素年代学研究结果表明,花岗斑岩LA-ICP-MS锆石U-Pb加权平均年龄为163.3±2.9 Ma,显示花岗斑岩体侵位于中侏罗世晚期.花岗斑岩具A型花岗岩特征,代表伸展构造岩浆活动.结合区域地质资料和前人相关研究,该区中侏罗世花岗斑岩可能形成于造山后伸展环境.花岗斑岩的期次厘定为松辽盆地的成生演化关系提供了新资料.     

中国中东部白垩纪沙漠的时空分布及其气候意义

本文介绍了中国中东部白垩纪沙漠沉积的时空分布，探讨了时空分布规律，认为：（１）中东部白垩纪沙漠分布严格受气候带控制，其实际分布限于北纬２０—４０°的干旱带（横跨当时的副热高压带），主要分布于鄂尔多斯盆地、四川盆地、江汉盆地和苏北盆地之中；（２）各盆地沙漠发生的时间不同，鄂尔多斯盆地为早白垩世，四川盆地为中白垩世晚期，江汉盆地为晚白垩世早期，苏北盆地为晚白垩世中期，（３）沙漠发生的穿时性反映了各盆地进入干旱带的顺序，由北到南，由西及东；（４）造成这种顺序的原因是由于亚洲在白垩纪时其总体为顺时针旋转，因而使西北部鄂尔多斯盆地率先进入干旱带，其次是西南部的四川盆地，然后是中部的江汉盆地。晚白垩世的降温事件迫使干旱带南移而使其滞后的最东部的苏北盆地进入干旱带，（５）中国白垩纪沙漠的存在说明处于“温室效应”的大气环流不仅不会“呆滞”而且还有所增强，季风的存在也说明当时的气候并不均一。本文提出了气候带漂变（ｃｌｉｍａｔｉｃｚｏｎｅｄｒｉｆｔ）的概念，认为气候变化的表现形式为气候带漂变。漂变既有长周期和短周期漂变之分，又有相对和绝对漂变之别。中国中东部白垩纪沙漠的时空变迁就是干旱气候带漂变的结果。