西藏岗巴晚白垩世有孔虫动物群与海平面变化

西藏南部岗巴地区上白垩统的有孔虫动物群十分丰富，经鉴定共有52属130种。根据岩性，该地区上白垩统可以划分出三个最基本的岩石地层单位：冷青热组、岗巴村口组及宗山组。依据其中有孔虫的形态结构、生态环境、系统演化及地史分布等特征，可以划分出五个主要的有孔虫动物群，Rotalipora动物群，Whiteinella-Helvetoglobotruncana动物群，Dicarinella-Marginotruncana动物群，Globotruncana-Globotuncanita动物群及Orbitoides-Omphalocyclus动物群。这五个有孔虫动物在晚白垩世相继绝灭，其绝灭与古水深有着十分密切的关系，主要是受海平面变化的影响。     

雅鲁藏布江南带白垩纪地层划分及特征

通过1∶25万区域地质调查,在藏南普兰县拉昂错—萨嘎县旦嘎东雅鲁藏布江结合带南带修康群中发现了大量放射虫化石,通过对该区沉积地层的详细调查,结合放射虫化石对原划修康群进行了充分解体,新厘定出侏罗系至始新统7个组级岩石地层单位,其中白垩系划分为折巴组与桑单林组。折巴组以杂色硅质岩、泥岩和页岩为主,夹砂岩、玄武岩等,与上覆上侏罗统旦嘎组和下伏下白垩统桑单林组呈整合接触关系,含丰富的早白垩世放射虫化石; 桑单林组以杂色石英砂岩、砂岩、泥岩、页岩及硅质岩为主,夹玄武岩等,整合于下白垩统折巴组与古近系蹬岗组之间,含丰富的晚白垩世放射虫与有孔虫化石。白垩系折巴组与桑单林组的建立与研究,丰富和完善了中生代特提斯洋盆区(雅鲁藏布江南带地层分区)的岩石地层沉积序列,提高了地层的研究水平,为研究该区沉积古地理环境和大地构造演化提供了新的基础资料。     

内蒙古平庄─元宝山盆地群晚中生代地层

平庄─元宝山盆地的晚中生代地层可划分为下白垩统黑水组、元宝山组和杏园组，上侏罗统上那不打组与那不打组。杏园组和元宝山组中含有丰富的植物化石，属于ＲｕｆｆｏｒｄｉａＯｎｙｃｈｉｏｐｓｉｓ植物群的中部组合，可与邻区的主要含煤沉积的植物组合进行对比，时代属早白垩世Ｂｅｒｒｉａｓｉａｎ期至早Ａｐｔｉａｎ期。     

淮安地区上白垩统孢粉化石新知

苏北盆地雀安断陷上白垩统盐系地层中发现了丰富的孢粉化石。根据孢粉型及被子植物演化特征命名为希指蕨孢属－克拉梭粉属孢粉化石带。自下而上，又细分为三个化石亚带：克拉梭粉属－希指蕨孢属－泉头粉属亚带、克拉梭粉属－希指蕨孢属－拟千屈菜粉属亚带和希指蕨孢属－克拉梭粉属－美丽粉属亚带。其时代分别为：森诺曼晚期、土仑早－中期和土仑晚期－森努力早、中期。当时古气侯为干旱的热带－亚热带气侯，十分有利于盐类矿床的沉积     

内蒙古平庄─元宝山盆地群晚中生代地层

平庄─元宝山盆地的晚中生代地层可划分为下白垩统黑水组、元宝山组和杏园组，上侏罗统上那不打组与那不打组。杏园组和元宝山组中含有丰富的植物化石，属于ＲｕｆｆｏｒｄｉａＯｎｙｃｈｉｏｐｓｉｓ植物群的中部组合，可与邻区的主要含煤沉积的植物组合进行对比，时代属早白垩世Ｂｅｒｒｉａｓｉａｎ期至早Ａｐｔｉａｎ期。     

黑龙江孙吴-嘉荫盆地白垩纪孢粉组合及地层划分对比

黑龙江孙吴—嘉荫盆地内两口地质探井获得的135块孢粉样品中含有孢粉化石87属,这些孢粉化石可以划分为4个孢粉组合,根据组合特征,这4个孢粉组合的地质时代分别为早白垩世凡兰吟期—欧特里沃期、阿尔必期,晚白垩世桑顿期—坎潘期、马斯特里赫特期,同时含这些孢粉化石的相关的白垩纪地层可以相应划分为下白垩统宁远村组、淘淇河组、上白垩统太平林场组和富饶组。这一研究为重新认识和建立孙吴—嘉荫盆地的地层层序提供重要的古生物依据。     

甘肃武都龙家沟盆地地层时代及发育特征

根据化石组合，龙家沟盆地的地层可划分为中侏罗统龙家沟组，上白垩统及上中新统保德组。龙家沟组是盆地的主体沉积，含有多层煤层及油页岩。保德组中发现有我国著名的“龙家沟三趾马动物群”．是保德期庙梁亚期的主要代表动物群之一。     

班公湖—怒江缝合带西段物玛地区原“晚古生代”混杂岩块中发现中生代化石

在班公湖—怒江缝合带西段铁杂—日雍构造混杂岩带物玛地区,原划为上石炭统拉嘎组地层中新发现了中生代孢粉化石14种及未定种,这些化石的发现为将该地层修订为下白垩统多尼组提供了古生物学依据。上石炭统拉嘎组被修订后,研究区班公湖—怒江缝合带不再存在拉嘎组混杂在中生代地层中的现象。同时本次研究在铁杂—日雍构造混杂岩带以南的冈底斯—腾冲地层区物玛分区原划为上石炭统拉嘎组中,发现中生代孢粉化石10种及未定种,并在其灰岩夹层中发现晚侏罗世珊瑚化石6种及未定种,同时在原划分为中二叠统下拉组中也发现晚侏罗世珊瑚化石。根据化石时代和区域地层对比,拉嘎组和下拉组分别被修定为上侏罗统萨波直不勒组和吐卡日组。至此,物玛分区的上侏罗统以萨波直不勒组和吐卡日组为代表,与其北侧的班公湖—怒江地层区上侏罗统可进行对比。本文以班公湖—怒江缝合带西段铁杂—日雍构造混杂岩带为例,证实在混杂岩带开展古生物学研究非常必要。     

班公湖—怒江缝合带西段物玛地区原“晚古生代”混杂岩块中发现中生代化石

在班公湖—怒江缝合带西段铁杂—日雍构造混杂岩带物玛地区,原划为上石炭统拉嘎组地层中新发现了中生代孢粉化石14种及未定种,这些化石的发现为将该地层修订为下白垩统多尼组提供了古生物学依据。上石炭统拉嘎组被修订后,研究区班公湖—怒江缝合带不再存在拉嘎组混杂在中生代地层中的现象。同时本次研究在铁杂—日雍构造混杂岩带以南的冈底斯—腾冲地层区物玛分区原划为上石炭统拉嘎组中,发现中生代孢粉化石10种及未定种,并在其灰岩夹层中发现晚侏罗世珊瑚化石6种及未定种,同时在原划分为中二叠统下拉组中也发现晚侏罗世珊瑚化石。根据化石时代和区域地层对比,拉嘎组和下拉组分别被修定为上侏罗统萨波直不勒组和吐卡日组。至此,物玛分区的上侏罗统以萨波直不勒组和吐卡日组为代表,与其北侧的班公湖—怒江地层区上侏罗统可进行对比。本文以班公湖—怒江缝合带西段铁杂—日雍构造混杂岩带为例,证实在混杂岩带开展古生物学研究非常必要。     

塔里木盆地草湖凹陷白垩纪湖相地层

塔里木盆地草湖凹陷白垩系皆分布于井下,以陆相沉积为主,下统自下而上为亚格列木组、舒善河组、巴西盖组与巴什基奇克组;首次发现上白垩统并命名为古城墟组。这套湖相地层中化石稀少,仅舒善河组中可划分出介形类Minheella-Damonella-Darwinula组合带,孢粉Classopollis-Lygodiumsporites-Schizaeosporites组合带和Dicheiropollis-Classopollis-Lygodiumsporites组合带。草湖凹陷白垩系以满2井序列最齐全且各单元岩电识别特征明显,可划分为3个Ⅱ级层序和6个Ⅲ级层序,湖盆沉积区的扩展以及各组横向分布明显的时空差异性强烈受燕山晚期构造运动的控制。     

Lithostratigraphy and depositional environments of the upper cretaceous deposits in the central Taurides (S Turkey)

The study area is located in the Central Taurides (southern Turkey), which is bounded by the K?rkkavak fault to the west and Ecemi? fault to the east. The sequences are studied in detail based on measured sections composed of the rocks deposited during the Cenomanian–Maastrichtian and located within different tectonic units previously described in the Taurides. The study materials include 217 thin section data from seven Cenomanian–Maastrichtian sequences of outcropping in different parts of the Central Taurides. The sediments deposited during the Cenomanian–Maastrichtian period in the Central Taurides are subdivided into eight units based on their lithological, paleontological, and textural properties. The lower boundaries of the upper Santonian and Campanian are unconformable contacts. The Upper Cretaceous sequence starts with the middle Cenomanian and represents a continuation of the Lower Cretaceous tidal flat and shelf lagoon sequence. Upper Turonian–Coniacian sediments are not observed due to the eustatic sea level drop. The second main transgression period of the Upper Cretaceous platform took place in the Santonian. This unit is represented by limestones composed of wackestones/packstones containing benthic foraminifera and rudist fragments, which are deposited in tidal flats and subtidal environments. The late Campanian starts with a transgression, and the environment transformed transitions into slope facies from inner platform facies, as a result of the thrust of ophiolitic rocks. In the following period, slope front and basin plain environments were dominant due to the increasing slope. Slumped pelagic limestones were deposited on the slope. Planktonic foraminiferal pelagic limestones were unconformably deposited on plaque limestone in the slope front environment depending on the increase in slope gradient and local faulting. As a result of decreasing tectonic activity, the sediments were deposited onto a stable basin plain. They were initially fed from the nearby carbonate platform and then by siliciclastic turbidites derived from the thrusted ophiolitic rocks. In this study, the lithostratigraphic properties of the Cenomanian–Maastrichtian units outcropping in various parts of the Central Taurides are described. The sedimentary deposits described here suggest different basinal conditions in the region.     

转换大陆边缘盆地深水浊积砂岩油气成藏差异性研究

深水浊积砂岩油气藏是当今世界油气勘探的热点领域。基于地震、钻井、地球化学等资料,系统分析了西非北段科特迪瓦盆地深水浊积砂岩油气成藏的差异性。研究表明,科特迪瓦盆地经历了裂陷期（早白垩世）和漂移期（晚白垩世—现今）两大构造演化阶段,漂移期发育塞诺曼—土伦阶优质海相烃源岩,裂陷期发育阿普特—阿尔布阶湖相烃源岩。漂移期层系为盆地的主力勘探层系,发育两种类型的浊积砂岩油气藏。塞诺曼—土伦阶浊积砂岩油气藏为典型的“砂体运移、自生自储、源内成藏”的油气成藏模式,其油气主要来源于塞诺曼—土伦阶烃源岩,广泛分布的浊积砂岩是油气运移的主要路径,烃源岩的生、排烃期决定了油气成藏时期,是否发育有效烃源岩是该类油气藏成藏的主控因素。圣通—马斯特里赫特阶浊积砂岩油气藏为典型的“断裂运移、下生上储、源外成藏”的油气成藏模式,其油气主要来源于深部裂陷期阿普特—阿尔布阶湖相烃源岩,断裂是油气运移的主要路径,断裂的活动控制了油气的运移和成藏时期,是否发育油源断裂是该类油气藏成藏的主控因素。     

Radiolarian paleobiogeography in the late Albian–Santonian

Radiolarian paleobiogeography for the late Albian–Santonian is proposed for the first time. The paleobiogeographic differentiation is found to be different for the Albian, Cenomanian, Turonian, and Coniacian–Santonian. The Tethyan and Boreal superrealms can be recognized for the Albian–Santonian. For the Albian–Santonian, the Tethyan Superrealm can be subdivided into realms: Atlantic-Mediterranean, Carpathian-Caucasian, and Tropical-Pacific. The boundaries of these realms changed throughout geological time. The Boreal Superrealm recognized for the Albian so far cannot be subdivided into realms, whereas in the Cenomanian it included the East European and Western Siberian realms without a clear definition of the boundaries and the Boreal-Pacific (in the North Pacific). The Boreal Superrealm is subdivided in the Turonian into two realms (European-Western Siberian and Boreal-Pacific), and in the Coniacian–Santonian, it is subdivided into three realms (European, Western Siberian, and Boreal-Pacific). The Austral Superrealm can be recognized only for the Albian and Cenomanian, and because of the lack of data, it cannot be delineated for the Turonian and Coniacian–Santonian.     

藏南定日地区白垩纪中期地球化学异常对海平面上升的响应

西藏南部定日地区在白垩纪中期为一套浅灰色-深灰色的陆源碎屑岩（钙质页岩）及碳酸盐岩（泥灰岩及微晶灰岩）的混积型沉积物，其中的地球化学特征变化反映了古海洋发生的重大变革。δ¹³ C的同位素曲线变化具有明显的低-高-低旋回变化，δ¹³ C正偏与有机碳大量埋藏、海平面上升及缺氧事件密切相关。铀、钍、钾的含量变化及Th/U比值的变化特征表明由海平面上升所形成的全球大洋缺氧的重要时期，由于有机物质及粘土矿物的增多，它们的含量均比标准平均值偏高。而⁸⁷Sr/ ⁸⁶Sr比值在该时期偏低，这也与当时的构造背景及海平面发生重大变化相一致。     

Variation on Foraminiferal Composition in Cretaceous Black-Gray-Red Bed Sequence of Southern Tibet, China

An Upper Cretaceous black-gray-red bed sequence was deposited in the Tethys-Himalayan Sea where abundant foraminifera, especially planktons, were yielded. In the shallow shelf to the upper slope on the north margin of Indian plate was recorded an extinction-recovery-radiation cycle of foraminiferal fauna highly sensitive to paleoceanographical changes. The black unit, consisting of the Late Cenomanian-earliest Turonian beds, displays a major extinction, with keeled planktonic and many benthic species as the principal victims at the end of the Cenomanian when existed only low diversity, sin-face water-dwelling foraminifera. The gray unit spans a long-term recovery interval from the Turonian to the early Santonian with keeled planktonic foraminifera returning stepwise to the water colunm. The planktonic biota in the red unit, extremely abundant, indicate a biotic radiation during the Late Santonian and the Early Campanian, implying that the high oxygen levels had returned to all the oceanic depth levels,and that the water stratification disappeared, followed by the radiation of all depth-dwellers. The variation on foraminiferal faunas from the whole sequence refers to the extreme warm climate that appeared in the Middle Cretaceous and to the declined temperature toward the late epoch. Substantial deposits for this warming and cooling zones represent the black shales in the Middle Cretaceous and the red beds in the later period of the southern Tibet. The change in the foraminiferal composition corresponded to the formation of dysaerobic facies and to the development of high-oxidized circumstances.     

Radiolarian-Based zonal scheme of the cretaceous (Albian–Santonain) of the Tethyan regions of Eurasia

A scheme of radiolarian zonal subdivision is proposed for the upper Albian–Santonian of the Tethyan regions of Eurasia. The upper Albian contains one zone: Crolanium triangulare; the Cenomanian contains three zones: Patellula spica (lower Cenomanian), Pseudoaulophacus lenticulatus (middle Cenomanian), and Triactoma parva (upper Cenomanian); the Turonian contains four zones: Acanthocircus tympanum (lower Turonian (with no upper part)), Patellula selbukhraensis (upper part of the lower Turonian), Phaseliforma turovi (middle Turonian (with no upper part)), and Actinomma (?) belbekense (upper part of the middle Turonian–upper Turonian); the Coniacian contains two zones: Alievium praegallowayi (lower part of the Coniacian) and Cyprodictyomitra longa (upper part of the Coniacian); the Santonian contains three zones: Theocampe urna (lower Santonian), Crucella robusta (middle Santonian–lower part of the upper(?) Santonian), and Afens perapediensis (upper part of the upper Santonian). The biostratigraphic subdivisions are correlated with biostrata in the schemes proposed previously for the Tethys and Pacific. A new species Patellula selbukhraensis Bragina sp. nov. is described.     

新疆西部乌依塔克组的时代

通过对新发现于新疆塔里木盆地西部上白垩统乌依塔克组有孔虫化石的时代分析，认为该组的时限为晚上伦期—赛诺期，综合分析各类化石的时代特征，本区土伦阶和赛诺阶的界线应划在Ｍｉｇｒｏｓ－Ａｍｍｏｂａｃｕｌｉｔｅｓ组合和Ｐａｒａｒｏｔａｌｉａ－Ｎｏｎｉｏｎｅｌｌａ组合之间。     

The heterodont bivalve Maghrebella forgemoli (Coquand, 1862) from Cenomanian of Batna,northeastern Algeria: Palaeobiogeography,biostratigraphy and palaeoenvironment

In the northern Aurès Range near Batna, Algeria, the Cenomanian Smail Marls Formation consists of fossiliferous deposits rich in diverse benthic macrofauna, mostly dominated by bivalves, among them the carditid Maghrebella forgemoli (Coquand, 1862). Almost exclusively Cenomanian, the abundance zone of Maghrebella forgemoli is in the higher levels of Lower Cenomanian, extending from the Sharpeiceras schlueteri zone to the Mantelliceras dixoni zone and corresponds to a limited circalittoral interval with relatively low energy, soft substrata, and relatively cold temperatures. The distribution of Maghrebella forgemoli in Mountains of Batna evidences bathymetric variation controlled by the tectonic activity affecting the ante-Triassic and the Upper Cretaceous substrata and generating a system of tilted blocks, at the beginning of the uppermost Albian-Cenomanian and Turonian, in the eastern Atlasic domain that extends to central Tunisia.     

Diachronisme des bassins turbiditiques d'avant-pays méso/néocrétacés du pays de Sault (Aude,Pyrénées françaises)

The cartographic, sedimentological and micropalaeontological analysis of remnants of Middle–Upper Cretaceous turbiditic basins from the ‘Pays de Sault’ (Aude, French Pyrenees) shows their diachronism (interpreted on a wider scale) and their sequence diversity. The ‘Gesse breccias’ are regarded as the proximal deposits of a Turonian narrow foreland basin, principally supplied by the erosion of the Jurassic–Lower Cretaceous cover of the High Primary Range to the south, induced by a strike-slip and overthrusting faulting within the en-échelon North-Pyrenean Fault Zone. More to the north, the North-Pyrenean ‘Axat Basin’ consists of two successive backstepping turbiditic wedges, respectively corresponding to an Upper Albian distal flysch and to a Middle–Upper Cenomanian more proximal flysch, all the series unconformably overlying structures that were folded then eroded before the Upper Albian. The previous concept of carbonate olistoliths included within the Axat Cenomanian flysch is also refuted: these large-size blocks are now interpreted as belonging to a tectonic slice destroyed and partly collapsed on the southern slope of the Rebenty Valley during the Quaternary. To cite this article: M.-J. Fondecave-Wallez, B. Peybernès, C. R. Geoscience 336 (2004).