内蒙古阿拉善地区的第三系及其动物群

笔者依据丰富翔实的资料,论述了该区第三地层的分布,区划,地层划分沿革,岩性,岩相古地理特征及地质演化史;在地层方面,首次在内蒙古西部建立了比较完整的第三纪地层序列;命名和划分了中始新统乌兰乌珠尔组,上始新统查干布拉格组。下渐新统乌兰塔塔尔组,上渐新统,下中新统乌尔较组,上中新统呼和好来组和上新统昂冈浩特组等６个地层单元,补充界定了查干布拉格组并将其时代厘定为晚始新世;在动物群方面,发现和命名了中始     

内蒙古淖尔套地区第三系的划分与对比

本文根据内蒙古阿拉善左旗淖尔套地区发现的乌尔图、乌兰塔塔尔和克克阿木三个动物群,厘定了上中新统呼和好来组,命名了下中新统乌尔图组和中渐新统乌兰塔塔尔组,还依岩性对比建立了下渐新统于咀陶组。     

我国陆相渐新世哺乳动物群的划分及排序

亚洲渐新世不是原认为的三分，而是仅包括两个期：早渐新世三达河期和晚渐新世塔奔布鲁克期。我国渐新世的地方动物群排序为：早渐新世包括（从早到晚）克克阿木、乌兰布拉格早期和乌兰布拉格晚期３个动物群；晚渐新世包括（从早到晚）４个动物群：沙嘎特动物群、塔奔布鲁克动物群、伊克布拉格动物群和索索泉动物群。“始新世末事件”在亚洲也很明显，主要表现为较原始的古老的哺乳动物在渐新世初就大量迅速绝灭。在渐新世期间，哺乳动物的变化主要表现为进化程度上的演变和替代。上述演变主要与当时全球的气候变冷、变干燥和亚洲地形的变化有关。     

广东雷州半岛晚渐新世—早更新世孢粉共存因子分析及古气候变化重建

广东省雷州半岛新生代钻孔ZKA01揭露的地层序列自下向上为渐新统涠洲组、中新统下洋组、角尾组、灯楼角组、上新统望楼港组、下更新统湛江组和中更新统北海组,涠洲组—望楼港组为滨浅海沉积,湛江组和北海组为陆相河湖相沉积。本文在ZKA01钻孔地层中自下向上88个层位中获取的29311粒孢粉化石的81个属中,选取了常见的种子植物花粉种属42个,通过共存因子分析法,定量重建了研究区晚渐新世—早更新世的古气候参数,划分出晚渐新世—早中新世(25~17 Ma)、中中新世(17~13.5 Ma)、晚中新世—上新世初期(13.5~4 Ma)和上新世—早更新世(4~1.5 Ma)4个气候演化阶段。孢粉共存因子定量法重建的研究区晚渐新世—早更新世4个阶段的古气候变化过程能较好地与全球气候变化的趋势相匹配,晚渐新世—早中新世温度降低的时间拐点大致可与Mi1a气候变冷事件相吻合。中中新世可以与中中新世气候适宜期(MMCO)相对应,表现为炎热潮湿的气候特征。中中新世晚期的气温是下降的,在一定程度上响应了Mi3中中新世气候变冷事件。     

潜江凹陷潜江组油气成藏期次及时间分析

基于圈闭形成时间法推测潜江凹陷潜江组油气藏形成的最早时间为上始新统潜二段沉积初期,利用烃源岩生排烃史法分析潜江凹陷潜江组油气成藏的最早时间为晚始新世,应用流体包裹体资料揭示潜江凹陷潜江组共经历了晚始新世-早渐新世(37~32 Ma)、早渐新世-中中新世(32~14 Ma)及中上新世-现今(3~0 Ma)共3期油气充注过程,并以第2期早渐新世-中中新世油气充注最为重要,且自蚌湖向斜带和潜北陡坡带至周矶向斜带再至斜坡带,油气充注时间有逐渐变晚的趋势。由此得出,综合应用流体包裹体法、圈闭形成时间法、烃源岩生排烃史法等多种方法可较为有效地确定具有复杂构造-沉积背景与演化历史的含油气盆地(凹陷)的油气成藏期次与时间。     

新疆乌伦古河地区第三纪哺乳动物群初析及地层年代确定

新疆准噶尔盆地北缘乌伦古河地区第三纪含有 7个哺乳动物群 :可可买登动物群 ,哈拉玛盖动物群 ,索索泉组顶部动物群 ,索索泉动物群 ,索索泉组底部 990 0 5动物群 ,铁尔斯哈巴合动物群和乌伦古河动物群。依据动物群分析初步确定 5个岩石地层单元的地质时代分别为 :可可买登组——中中新世晚期 ;哈拉玛盖组——中中新世早期 ,索索泉组——最早中新世至早中新世最晚期或中中新世最早期 ;铁尔斯哈巴合组——晚渐新世 ;乌伦古河组——早始新世至早渐新世。     

南海陆缘盆地构造演化与烃源岩特征

受近南北向扩张机制控制,南海陆缘盆地或凹陷多呈NE向带状展布,总体上具有“南三北三”平行排列、外窄内宽的特点。新生代发生的4次重要区域构造运动具有穿时性,共发育3期盆地破裂不整合面,分别是早渐新世与晚渐新世之间、古近纪与新近纪之间、中中新世与晚中新世之间;由东往西,盆地破裂不整合面的时代逐渐变新。受构造运动与海平面升降影响,南海海域发育湖相、海陆过渡相和陆源海相3类烃源岩。由南北两侧向中央海盆,烃源岩类型由湖相逐渐过渡到海陆过渡相与陆源海相;从东向西,盆地主力烃源岩层位逐渐变新,由始新统-渐新统逐渐过渡到渐新统-中新统。南海海域烃源岩的分布规律与盆地破裂不整面存在密切关系:破裂不整合面形成早（早渐新世与晚渐新世之间）的盆地,主力烃源岩形成早（始新统湖相烃源岩）;反之,破裂不整合面形成晚（中中新世与晚中新世之间）的盆地,则烃源岩形成晚（渐新统-中新统海陆过渡相到陆源海相烃源岩）。     

菲律宾海盆东北部晚始新世以来放射虫及其古海洋学意义

研究了菲律宾海盆东北部“大洋钻探工程”１２５航次７８２Ａ孔晚始新世以来的放射虫化石。根据Ｓａｎｆｉｌｉｐｐｏ等１９８５年的分带,将研究区自下而上划分为１０个带。讨论了始新世与渐新世、渐新世与中新世、中中新世与晚中新世、中新世与上新世以及上新世与第四纪的界线。研究区存在两个沉积间断,分别位于晚渐新世与早中新世晚期之间和中中新世与晚中新世之间。研究区第四纪放射虫化石仍以暖水分子为主,冷水分子分布较浅。依据放射虫化石分异度曲线得出,晚第三纪以来本区存在５个相对暖水期和５个相对较凉期,渐新世时处于冷水期,这与钙质超微化石复合分异度和碳酸钙含量曲线的变化是一致的。晚渐新世与早中新世晚期之间的沉积间断是由于中新世南极冰盖扩展造成大洋底层洋流活动加剧而形成的。     

南沙海西南部油气地质条件分析及油气远景预测

南沙海域西南部具有上始新统－下渐新统、上渐新统－中中新统、上中新统三套油气源岩，其有机质类型属ⅡＢ－Ⅲ干酪根。根据ＤａｖｉｄＡ．Ｗｏｏｄ（１９８８）计算不同地层的７７７值和Ｒ０值，确定了研究区的生油门限深度，万安盆地南部为１７００－３５００ｍ，曾母盆地西北部为１５００－３５００ｍ，并分析了有机质成熟度的热演化史。研究区发育有三类储集层：渐新世－晚中新世砂岩、中－晚中新世台地灰岩或礁灰岩和前第三纪裂     

陕西渭河地区新生代地层及沉积环境演化

渭河地区新生代地层十分发育,前人做了大量工作,但详细的地层划分一直存在不同认识。随着近些年渭河地区研究工作的不断进展,结合前人已有的成果,通过大量野外剖面实测及室内资料的汇总,对渭河地区新生代地层做了归纳,划分如下:古近系始新统红河组;渐新统白鹿塬组;新近系中新统冷水沟组、寇家村组、灞河组;上新统游河组;第四系更新统三门组、泄湖组、乾县组及全新统半坡组。渭河地区由始新世开始沉积,早期气候比较炎热干燥,渐新世逐渐变得温暖湿润,至渐新世晚期气候干冷;中新世早期湖泊广布,环境相对湿润,晚期逐渐变得干暖,但依然存在干冷环境;上新世整体比较温暖湿润,但后期气候逐渐转凉;至第四纪随着冰期到来,整体气候显著变冷、变干,半湿润半干旱气候形成。     

南海北部深水区LS33a钻井微体古生物年代地层格架

南海北部琼东南盆地深水区接收了渐新世以来数千米厚的海相沉积地层,蕴藏着丰富的微体古生物化石。对深水区LS33a钻井岩芯的取样和化石鉴定,识别出21个浮游有孔虫化石带（N22带～P19带）和12个钙质超微化石带（NN19带～NP24带）。通过与大洋钻探（ODP）在南海实施的184航次的钻探结果和“国际年代地层表（2012）”等的对比分析,探讨了化石事件的地质年代意义,构建了LS33a钻井生物年代地层格架。在此基础上,讨论了更新统与上新统、上上新统与下上新统、上新统与中新统、上中新统与中中新统、中中新统与下中新统、中新统与渐新统、上渐新统与下渐新统之间地层界线位置以及崖城组、陵水组、三亚组、梅山组、黄流组、莺歌海组和乐东组地层的时代归属,建立了适用于南海北部深水区的高分辨率综合年代地层格架。     

Lithostratigraphy and planktonic foraminiferal biostratigraphy of the late Eocene-Middle Miocene sequence in the area between Wadi Al Zeitun and Wadi Al Rahib,Al Bardia area,northeast Libya

The present study deals with the lithostratigraphy and planktonic foraminiferal biostratigraphy of the Late Eocene-Middle Miocene sequence in the Al Bardia area, northeast Libya. The lithostratigraphical studies carried out on three stratigraphical surface sections, namely Wade Al Rahib, Wadi Al Hash and Wadi Al Zeitun, led to the recognition of three rock units from base to top: (1) the Al Khowaymat Formation (Late Eocene-Early Oligocene); (2) the Al Faidiyah Formation (Late Oligocene-Early Miocene); and (3) the Al Jaghboub Formation (Early-Middle Miocene). The planktonic foraminiferal biostratigraphical analysis led also to the recognition of nine planktonic foraminiferal zones ranged in age from Late Eocene to Early Miocene with one larger foraminiferal zone of Middle Miocene age. These are, from base to top, as follows: Truncorotaloides rohri Zone (Late-Middle Eocene, Lutetian), Globigerinatheka semiinvoluta and Turborotalia cerroazulensis s.l. Zones (Late Eocene, Priaborian), Cassigerinella chipolensis/Pseudohasitgerina micra Zone (Early Oligocene, Rupelian), Globigerina ciperoensis ciperoensis, Globorotalia kugleri Zones (Late Oligocene, Chattian), Globigerinoides primordius Zone (Early Miocene, Aquitanian), Globigerinoides altiaperturus/Catapsydrax dissimilis and Globigerinoides trilobus Zones (Early Miocene, Burdigalian), and the larger benthonic foraminiferal zone, Borelis melo melo Zone (Middle Miocene, Langhian to Serravallian). The study of planktonic foraminifera proved the existence of a regional unconformity between the Early and Late Oligocene, with the Middle Oligocene deposits being absent (absence of Globigerina ampliapertura and Globorotalia opima opima Zones), and another, smaller unconformity located between the Late Eocene and Early Oligocene, in which the uppermost part of the Late Eocene is missing.     

西太平洋782A钻孔新生代的有孔虫

大洋钻探工程” 1 2 5航次的 782 A钻孔位于西太平洋菲律宾海东北部 ,井深 4 76.8m。基底为安山岩 ,上覆盖层为中始新统—更新统的沉积层 ,其中保存有低丰度的有孔虫。自下而上可划分出 8个浮游有孔虫带。由于出现 Catapsydrax dissimilis,C.stainforthi为 N5 、N6 带的带化石 ,表明本钻孔存在早中新世的地层。同时由于缺失浮游有孔虫带 P1 5 — P1 6 下部 ,N3上部—N4,N7—N1 1 带的带化石 ,说明在中始新世与晚始新世之间、晚渐新世与早中新世之间、早中新世与中中新世之间存在 3个沉积间断。钻孔中的有孔虫标志本区当时处于温暖亚热带环境。根据不同时期温度的变化 ,可划分出 5个阶段 ,包括 3个偏暖时期和 2个温凉时期。     

Cenozoic stratigraphy of the Sahara,Northern Africa

This paper presents an overview of the Cenozoic stratigraphic record in the Sahara, and shows that the strata display some remarkably similar characteristics across much of the region. In fact, some lithologies of certain ages are exceptionally widespread and persistent, and many of the changes from one lithology to another appear to have been relatively synchronous across the Sahara. The general stratigraphic succession is that of a transition from early Cenozoic carbonate strata to late Cenozoic siliciclastic strata. This transition in lithology coincides with a long-term eustatic fall in sea level since the middle Cretaceous and with a global climate transition from a Late Cretaceous–Early Eocene “warm mode” to a Late Eocene–Quaternary “cool mode”. Much of the shorter-term stratigraphic variability in the Sahara (and even the regional unconformities) also can be correlated with specific changes in sea level, climate, and tectonic activity during the Cenozoic. Specifically, Paleocene and Eocene carbonate strata and phosphate are suggestive of a warm and humid climate, whereas latest Eocene evaporitic strata (and an end-Eocene regional unconformity) are correlated with a eustatic fall in sea level, the build-up of ice in Antarctica, and the appearance of relatively arid climates in the Sahara. The absence of Oligocene strata throughout much of the Sahara is attributed to the effects of generally low eustatic sea level during the Oligocene and tectonic uplift in certain areas during the Late Eocene and Oligocene. Miocene sandstone and conglomerate are attributed to the effects of continued tectonic uplift around the Sahara, generally low eustatic sea level, and enough rainfall to support the development of extensive fluvial systems. Middle–Upper Miocene carbonate strata accumulated in northern Libya in response to a eustatic rise in sea level, whereas Upper Miocene mudstone accumulated along the south side of the Atlas Mountains because uplift of the mountains blocked fluvial access to the Mediterranean Sea. Uppermost Miocene evaporites (and an end-Miocene regional unconformity) in the northern Sahara are correlated with the Messinian desiccation of the Mediterranean Sea. Abundant and widespread Pliocene paleosols are attributed to the onset of relatively arid climate conditions and (or) greater variability of climate conditions, and the appearance of persistent and widespread eolian sediments in the Sahara is coincident with the major glaciation in the northern hemisphere during the Pliocene.     

Sea-level fluctuations on the northern shelf of the Eastern Paratethys in the Oligocene-Neogene

Sea-level fluctuations in the terminal Eocene, Oligocene, and Neogene of the Eastern Paratethys are quantitatively assessed on the basis of facies and old coastlines traced on the northern platform shelf, levels of river valley incisions, and the study of seismic profiles. The first data massif allows the characterization and correlation of transgression stages in the history of the Eastern Paratethys. The greatest transgressions fall within the first half of the Late Eocene, mid-Early Oligocene, initial Late Oligocene, initial Early Miocene, the initial Tchokrakian, Karaganian and Sarmatian in the Middle Miocene, the middle and late Sarmatian and early Pontian in the Late Miocene, and the Akchagylian in the Caspian basin of the Pliocene. In contrast, the greatest incisions of northern rivers running from the platform allow us to establish the time and extent of the main declines in the base levels of the erosion. Maximal incisions date back to the terminal Eocene-initial Oligocene, terminal Solenovian time in the terminal Rupelian, the terminal Maikop in the Early Miocene, the terminal Sarmatian and middle Pontian in the Late Miocene, and the Early Pliocene in the Caspian basin. Large regressions also formed unconformity surfaces, traced on seismic profiles as erosion boundaries of several orders. The surfaces are confined to the Eocene/Oligocene boundary, middle and late Maikop, Sarmatian/Meotian boundary, middle Pontian, and terminal Miocene-initial Pliocene, as well as being traced even in the most deep-water basins. The synthesis of these data suggests a preliminary version for the curve of transgression-regression cyclicity. Its correlation with the eustatic curve shows their similarity only in the lower part-prior to the initial Middle Miocene, when Paratethys became a semi-closed basin.     

Tropical/subtropical Upper Paleocene–Lower Eocene fluvial deposits in eastern central Patagonia,Chile (46°45′S)

A succession of quartz-rich fluvial sandstones and siltstones derived from a mainly rhyolitic source and minor metamorphic rocks, located to the west, represent the first Upper Paleocene–Early Eocene deposits described in Chilean eastern central Patagonian Cordillera (46°45′S). This unit, exposed 25 km south of Chile Chico, south of lago General Carrera, is here defined as the Ligorio Márquez Formation. It overlies with an angular unconformity Lower Cretaceous shallow marine sedimentary rocks (Cerro Colorado Formation) and subaerial tuffs that have yielded K–Ar dates of 128, 125 and 123 Ma (Flamencos Tuffs, of the Divisadero Group). The Ligorio Márquez Formation includes flora indicative of a tropical/subtropical climate, and its deposition took place during the initial part of the Late Paleocene–Early Eocene Cenozoic optimum. The underlying Lower Cretaceous units exhibit folding and faulting, implying a pre-Paleocene–Lower Eocene contractional tectonism. Overlying Oligocene–Miocene marine and continental facies in the same area exhibit thrusts and normal faults indicative of post-Lower Miocene contractional tectonism.     

Sequence of the Cenozoic Mammalian Faunas of the Linxia Basin in Gansu, China

In the Linxia Basin on the northeast margin of the Tibetan Plateau, the Cenozoic strata are very thick and well exposed. Abundant mammalian fossils are discovered in the deposits from the Late Oligocene to the Early Pleistocene. The Dzungariotherium fauna comes from the sandstones of the Jiaozigou Formation, including many representative Late Oligocene taxa. The Platybelodon fauna comes from the sandstones of the Dongxiang Formation and the conglomerates of the Laogou Formation, and its fossils are typical Middle Miocene forms, such as Hemicyon, Amphicyon, Platybelodon, Choerolophodon, Anchitherium, and Hispanotherium. The Hipparion fauna comes from the red clay of the Liushu and Hewangjia Formations, and its fossils can be distinctly divided into four levels, including three Late Miocene levels and one Early Pliocene level. In the Linxia Basin, the Hipparion fauna has the richest mammalian fossils. The Equus fauna comes from the Wucheng Loess, and it is slightly older than that of the classical Early Pl     

伦坡拉盆地西部丁青湖组新发现凝灰岩锆石U- Pb年龄及其地层学意义

伦坡拉盆地丁青湖组沉积时代的确定对于研究青藏高原中部的古高度和古气候具有重要的地质意义,但由于没有精确的年龄数据,其顶部是否跨入了新近系,一直以来都存在争论。作者在伦坡拉盆地西部鄂加卒地区开展野外调查过程中,在该剖面中部和上部新发现两套凝灰岩夹层,对凝灰岩进行了LA-ICP-MS锆石U-Pb定年,获得了两件凝灰岩样品的形成年龄分别为24.05±0.24Ma(MSWD=1.07,n=24)和22.64±0.33Ma(MSWD=0.45,n=17),时代分别为晚渐新世和早中新世。根据凝灰岩锆石U-Pb年龄和前人研究成果,将鄂加卒剖面的细碎屑岩地层重新厘定为丁青湖组,并将丁青湖组的沉积时代定为渐新世-中中新世。根据丁青湖组地层厚度及沉积速率估算,该组沉积持续时间在21～23Ma之间,其顶部地层的年龄在11～13Ma左右。由此可见,伦坡拉盆地接受连续沉积一直持续到了中中新世,这比过去普遍认识的晚始新世-渐新世时期青藏高原中部的古高度和古气候变化时间更晚。前人在该地区发现的近无角犀化石、攀鲈鱼化石、棕榈科叶片化石以及孢粉化石等研究结果共同证实,青藏高原中部渐新世晚期的古海拔高度低于～2500～3000 m。因此,该区晚渐新世-早中新世温暖潮湿的气候特征很可能是受到了印度洋气流穿透的影响,而且该影响可能一直持续到了中中新世,从而造就了该时期青藏高原生物的多样性。