青海西南部海相侏罗纪地层新认识

本文通过综合研究雀莫错等三条剖面及其中丰富的古生物资料和沉积旋同、岩石组合特征等,将青海西南部唐古拉山地区的侏罗系划分为中侏罗统雀莫错组、沱沱河组、布曲组、夏里组和上侏罗统索瓦组、扎窝茸组共六个地方性地层单位,并叙述和讨论了这些地层单位(包括部分新发现地层)的沉积特征与地质时代,还简要分析了该区侏罗纪古地理环境。     

中国侏罗纪年代地层学研究的现状

“国际地层表”依据菊石带建立起来的侏罗纪年代地层系统在全球海相侏罗系的划分和对比中有着广泛的应用,但却很难直接应用于非海相侏罗纪地层系统中。中国的侏罗系多属非海相,近年来我国地质工作者们不但将中国的海相侏罗系与全球侏罗纪年代地层系统进行了较合理的对比,发现了穿越海相三叠系-侏罗系界线的连续沉积的剖面,而且建立了非海相侏罗系的阶。但是中国非海相侏罗系区域性阶的时代和不同阶之间的界线有待海相化石和地层测年来确定或检验     

塔里木盆地中新生代海侵和海相地层研究的新进展

中新生代海侵是塔里木盆地地质发展史上的重要事件之一。通过对新近发现的古生物化石和海相地层资料研究，本文提出了早白垩世、晚白垩世、古近纪的海侵范围的新认识。同时，依据露头和钻井资料提出了中新世海水分布的新范围。这些新成果对厘定塔里木盆地中新生代地层时代，建立整个盆地中新生代地层格架和油气远景分析具有重要意义。     

我国海相地层有机地化研究现状：第六届全国有机地球化学学术会议侧记

第六届全国有机地球化学学术会议于1996年5月8～14日在四川省峨眉市召开,这次会议共有来自中国石油天然气总公司、海洋石油总公司、中科院、煤炭部和地矿部五大系统46个单位的198名代表参加,会议内容包括石油地球化学(生油理论、勘探综合研究实例等)、天然气与凝析油地球化学、非     

中国海相油气地质勘探与研究--访李德生院士

李德生,1922年生,江苏苏州人。中国科学院院士,第三世界科学院院士。1945年毕业于中央大学地质系。主要从事石油勘探、开发和地质研究工作。曾在玉门、台湾、大庆、胜利、四川、大港和任丘等油气田从事勘探开发等生产实践工作。1978年以后任中国石油天然气集团公司北京石油勘探     

福建沿海晚第四纪海相地层的初步研究

<正> 福建沿海第四纪地层发育,以晚第四纪海相地层为主。前人做了许多工作。但对地表露头进行年代学和沉积环境研究的较少,缺少在同一剖面同时获得测年数据和指相化石。     

甘溪剖面泥盆纪海相碳酸盐岩的同位素地层曲线

甘溪剖面泥盆纪海相碳酸盐岩的同位素地层曲线卢武长，崔秉荃，杨绍全，张平（成都地质学院）海相碳酸盐的同位素演化很早就引起人们注意Ｚ１９３６年Ｎｉｅｒ和Ｇｕｌｂｒｓｎｓｅｎ首次研究海相石灰岩的碳同位素组成。１９５１年Ｕｒｅｖ测定了箭石的氧同位素。     

论塔里木盆地西部海相古新统划分

塔里木盆地古部海相古新统原来由陈尔塔什组和齐姆根两个组构成，根据在陈尔塔什组下伏地层－吐依洛克组发的有孔虫组合和介形虫的时代，本文将该组厘定为古新统Ｄａｎｉａｎ阶而非上白垩统，本文从生物地层学、事件地层学、稳定同位素地层学，古气候学和地球化学五个方面确定了古新统的底界；提出了古新统划分新方案，即自下而上包括吐依洛克组、阿尔塔什组和刘姆根组三个组；划分出古新统五个有孔虫组合，其中两个为新建；文中还描     

断裂系统在油气成藏中的应用

断裂系统在油气地质及成藏规律研究中具有重要意义,对于勘探和研究程度较低或很低的地区,应拓宽思路,充分利用各个地区的有利条件,开展多样的勘探和研究工作,在充分依靠先进勘探技术的同时,还应重视地面地质调查,尤其是重视已发现的地表油苗价值的开发,江西弋阳盆地和浙江金衢盆地白垩系红色砂质岩层内广泛分布裂缝性含油,含沥青显示说明,其分布明显受区域性断裂系统的控制,断裂系统与孔生相对较好的砂质岩配置,可形成地     

Hydrocarbon Accumulation Process in the Marine Strata in Jianghan Plain Area,Middle China

Marine strata in the Jianghan Plain area are widely distributed with a total depth of more than 8,000 m from the Upper Sinian to the Middle Triassic. Six reservoir caprock units, named Z–∈2, ∈2–O, S, D–C, P and T1, can be identified with each epoch. The geology, stratigraphy, drilling, oil testing and other basic data as well as the measured inclusion and strontium isotope data in the study area are used in the analysis of the formation and evolution process of marine petroliferous reservoirs in the Jianghan Plain area. This study aims to provide a scientific basis for the further exploration of hydrocarbons in the Jianghan Plain and reduce the risks by analyzing the key factors for hydrocarbon accumulation in the marine strata. Our findings show that in the Lower Palaeozoic hydrocarbon reservoir, oil/gas migration and accumulation chiefly occurred in the early period of the Early Yanshanian, and the hydrocarbon reservoir was destroyed in the middle–late period of the Early Yanshanian. In the Lower Triassic–Carboniferous hydrocarbon reservoir, oil/gas migration and accumulation chiefly occurred in the Early Yanshanian, and the hydrocarbon reservoir suffered destruction from the Late Yanshanian to the Early Himalayanian. The preservation conditions of the marine strata in the Jianghan Plain area have been improved since the Late Himalayanian. However, because all source beds have missed the oil/gas generation fastigium and lost the capacity to generate secondary hydrocarbon, no reaccumulation of hydrocarbons can be detected in the study area's marine strata. No industrially exploitable oil/gas reservoir has been discovered in the marine strata of Jianghan Plain area since exploration began in 1958. This study confirms that petroliferous reservoirs in the marine strata have been completely destroyed, and that poor preservation conditions are the primary factor leading to unsuccessful hydrocarbon exploration. It is safely concluded that hydrocarbon exploration in the marine strata of the study area is quite risky.     

Unit stratotypes for global stages: The Neogene perspective

Recent developments in integrated high-resolution stratigraphy and astronomical tuning of continuous deep marine successions invalidate arguments against the designation of unit stratotypes for global stages, the basic building blocks of the standard Global Chronostratigraphic Scale (GCS). For the late Neogene, Global Stratotype Section and Point (GSSP) sections may also serve as unit stratotypes, covering the interval from the base of a stage up to the level that–time-stratigraphically–correlates with the base of the next younger stage in a continuous and well-tuned deep marine succession. The added value of such sections as unit stratotype lies in the integrated high-resolution stratigraphy and astronomical tuning, which combined, provides an excellent age control with an unprecedented resolution, precision and accuracy within the entire stage. As such they form the backbone of the new integrated late Neogene time scale and provide the basis for reconstructing Earth's history. In this way a stage is also defined by its content and not only by its boundaries. Our unit stratotype concept strengthens the importance of time-rock units by allowing the introduction of astronomically defined chronozones as formal chronostratigraphic units, thereby arguing against the elimination of the dual classification of chronostratigraphy and geochronology.Extending this concept to older time intervals requires that well-tuned, continuous deep marine sections are employed, thus necessitating the employment of multiple hole (I)ODP sites for defining (remaining) stages and stage boundaries in at least the Cenozoic and Cretaceous and possibly the entire Mesozoic. Evidently the construction of the Geological Time Scale (including the GCS) should be based on the most appropriate sections available while, where possible, taking the historical concept of global stages into account.     

Quantitative Biostratigraphic Analysis upon the Upper Cretaceous in Tethyan Himalaya

Biostratigraphic analysis is an essential element for understanding global tectonics and the evolution of life on Earth. Quantitative analysis of sedimentary sequences provides the precise age constraints on timing of significant events in Earth’s history. This paper presents results from quantitative stratigraphic analysis of Upper Cretaceous Tethyan Himalayan sequences. This analysis resulted in a new composite stratigraphic section for the Cretaceous strata of Tibet (TIBETKCS). The eight Upper Cretaceous sections were analyzed in this study and 12 planktonic foraminifera zones were recognized based on available data. Quantitative measurements were made using a Graphic Correlation with Graphcor 3.0 software and correlated to the world standard Cretaceous Composite Section (MIDKCS). The sections were also examined using Constrained Optimization software by CONOP9. Level Penalty was applied as the rule to measure misfit among automatically correlated sections. The new TIBETKCS correlates well with planktonic foraminifera ages from previous work in southern Tibet. A fitting equation of y=?0.19x+305 with a correlation coefficient of 0.94 was obtained from this work. The ages of the first and last appearances of 64 planktonic foraminifera can be calculated with this equation with ± 0.3 Ma precision. This level of precision is approximately 10 times higher than age determinations with traditional methods. Two extinction events were resolved within this analysis at ~93.5 Ma and ~85.5 Ma corresponding to the Ocean Anoxic Events at Cenomanian–Turonian and Coniacian–Santonian boundaries respectively.     

The biostratigraphy of the uppermost calcareous nannofossils of Cretaceous deposit in both Shahdar and Namazgah sections (NE Iran)

A moderately various calcareous nannofossil assemblage of 44 species assigned to 24 genera is identified in samples collected from the Shahdar section and 18 genera and 43 species in Namazgah section. Testing of calcareous nannofossil has permitted recognition of few important coccolith events in stratigraphic interval occupied by the uppermost layers of Cretaceous in the Shahdar and Namazgah sections. These events are correlated to the CC24–CC26 of Sissingh (Geol Minjbouw 56: 37–65, 1977) in two sections. According to these biozones, the age of the studied sections in Shahdar and Namazgah is Early Maastrichtian–Late Maastrichtian. On the basis of paleoecological interpretation, the last layers related to the Cretaceous deposits in two sections were deposited in shallow marine environment in relatively low latitude, and the depth of the basin from the Cretaceous deposits toward Fajan Formation is minimized.     

The Roadian Stage of the Permian and problems of its global correlation

Ammonoids, conodonts, and fusulinids from the type sections of the Roadian and contiguous stages in western Texas and adjacent areas are analyzed and partially revised. Four successive Roadian ammonoid assemblages are distinguished and correlated with conodont zones; data on their distribution are presented. Based on the results obtained, the Roadian Stage is identified in the Boreal and Tethyan regions. Boundaries of the Roadian Stage defined accurately in the type sections of Texas are hardly recognizable elsewhere. Recognition of the upper boundary is especially difficult. Occurrence of Roadian fossils means that deposits of this age are present in a sequence, but they cannot be differentiated from underlying and overlying beds. Like in the type area, the stage lower boundary based on conodonts is above the level of significant changes in marine biota within the Boreal and Tethyan realms as well. The upper boundary is not marked by noticeable biotic events either. Correlation of the Roadian deposits is imprecise because their boundaries are formally established using distribution of relatively rare conodonts.     

The Upper Jurassic–Lower Cretaceous of eastern Heilongjiang, northeast China: stratigraphy and regional basin history

In eastern Heilongjiang, the Upper Jurassic is marine and restricted to the Suibin and Dong’an areas, where it is characterized faunally by Callovian–Volgian (Tithonian) bivalves and florally by dinoflagellates. The Lower Cretaceous is widely distributed in eastern Heilongjiang, and characterized faunally by Berriasian–Valanginian bivalves, Barremian–Albian ammonites and Aucellina, and florally by dinoflagellates. To the west, the marine facies grade into non-marine beds. Thus, in the east, for example in the Dong’an and Dajiashan areas, near the northwestern Palaeo-Pacific, the Lower Cretaceous is marine; westward, in the Yunshan, Longzhaogou, Peide, and Zhushan areas, marine and non-marine deposits alternate, whereas further west still, e.g. in the Jixi Basin, non-marine facies are intercalated with marine beds. This regional distribution is indicative of a large, shallow embayment opening eastwards to the Palaeo-Pacific; during the Early Cretaceous successive transgressive-regressive events influenced the climate and biota of eastern Heilongjiang and northeastern China. Many of the Lower Cretaceous sections contain abundant coals, demonstrating that in this region the Early Cretaceous was an important coal-forming period. Some non-marine bivalve species are common to the Lower Cretaceous Jixi Group of eastern Heilongjiang, the Jehol Group of western Liaoning and the Transbaikalian Group of Siberia, suggesting that these groups are of comparable Early Cretaceous age.     

藏南江孜地区早白垩世甲不拉组钙质超微化石的特征及其地层意义

藏南江孜一带的侏罗纪—白垩纪海相地层被划分为维美组和甲不拉组。通过偏光显微镜和扫描电镜观察和分析,发现甲不拉组黑色页岩中含有保存较为完好的钙质超微化石。研究区的生物丰度和分异度偏低,经鉴定以椭圆球石科(Ellip-sagelosphaeraceae)生物群为主,数量相对丰富,但属种比较单调。超微化石指示甲不拉组为早白垩世沉积的产物。结合菊石和双壳类化石,认为甲不拉组地层时代属于早白垩世贝利阿斯期至凡兰吟期(Berriasian-Valanginian)。这一发现标志着西藏特提斯东部早白垩世地层中钙质超微化石的存在。甲不拉组早白垩世钙质超微化石的发现,为该地区海相地层的时代划分、对比提供了新的资料,也为寻找海相侏罗纪—白垩纪地层界线指示了目标。     

藏南江孜地区早白垩世甲不拉组钙质超微化石的特征及其地层意义

藏南江孜一带的侏罗纪—白垩纪海相地层被划分为维美组和甲不拉组。通过偏光显微镜和扫描电镜观察和分析,发现甲不拉组黑色页岩中含有保存较为完好的钙质超微化石。研究区的生物丰度和分异度偏低,经鉴定以椭圆球石科（Ellip-sagelosphaeraceae）生物群为主,数量相对丰富,但属种比较单调。超微化石指示甲不拉组为早白垩世沉积的产物。结合菊石和双壳类化石,认为甲不拉组地层时代属于早白垩世贝利阿斯期至凡兰吟期（Berriasian-Valanginian）。这一发现标志着西藏特提斯东部早白垩世地层中钙质超微化石的存在。甲不拉组早白垩世钙质超微化石的发现,为该地区海相地层的时代划分、对比提供了新的资料,也为寻找海相侏罗纪—白垩纪地层界线指示了目标。     

非海相白垩系年代学和对比

从1800年代初最早确定的白垩系定义起,白垩系就包括了海相和非海相白垩纪的地层和化石。白垩纪是一个全球性气候温暖、海平面高、构造和火山活动强烈的世界。此时,多块大陆分解,几乎所有海洋都已打开,形成了与现代相近的海陆分布的地理图案。这一变革导致了全球生物群的区域化,给全球对比带来了困难。白垩纪的全球年代地层表是主要依据菊石和微体生物(有孔虫和钙质超微浮游生物)化石,并与已完整建立的全球极性倒转年表和很多放射性同位素年龄相结合的产物。从孢粉到恐龙等各类非海相化石均已用于白垩纪生物地层学。此期专刊的特色是聚焦于区域或全球的孢粉(包括沟鞭藻)、大植物、甲壳类(包括叶肢介和介形类)、软体动物(包括腹足类和双壳类)和脊椎动物(包括硬躯体和足印)非海相白垩纪生物地层学和生物年代学。这些研究大大扩展了非海相白垩系对比的内容,并强调了将能取得更多进展的研究方向。非海相地层和化石群中直接夹有海相地层和化石的剖面/地区的非海相生物地层学更精确的研究,高分辨率的微体化石,特别是既出现于非海相又见于海相地层中的微体化石的微体生物地层学的进展,更多的直接与非海相生物地层学相关的放射性同位素和古地磁年龄的测试,非海相地层的高分辨率层序和旋回地层学分析及与非海相生物地层学对比的化学地层学的发展等,均将促进全球非海相白垩纪地层时代和对比,甚至以国际地质时标为准绳的全球非海相白垩纪地层对比框架表的建立。     

Aptian综合年代地层事件:定量地层学的运用

以往发表的年代地层数据都是以Ma形式出现,以关键物种的首现面和末现面来界定的。一般而言,这些年龄是在用某种方法确定的某两个层的年龄基础上通过插值获得的,很大程度上仍然是估计值,而不是可以检验的科学结论。我们需要的是一个可以评价的、剖面重现的、标本重现的而且插值方法是经过严格检验的数据库。图形对比技术正是一个有用的方法,它可以综合众多剖面的分散分布的事件,并可以验证这些事件的顺序和年代。图形对比技术是一个定量的、非统计的方法,可以判别两个剖面之间存在的同时代关系。物种时限和非生物事件投点到X/Y图解上,时限可以通过对比线综合到单个的时间尺度上。其他剖面的数据通过重复以上过程把每个剖面的数据综合进来。获得的时限通过评价有这些物种出现的图形解而得到验证。Aptian阶(约124~112 Ma)时期环境发生巨大变化,用来确定Aptian阶的许多关键生物事件和年代地层事件并不都出现在同一个剖面。因此,这些事件的相对年龄始终是不确定的,也不是相关的。两个事件被提出来用于界定Aptian 阶的底界,包括菊石Deshayesites tuarkyricus 和磁极性带CM0。然而这两个事件标准地层剖面相隔600 km。图形对比显示这两次事件出现在7 万年间隔内。通过这一方法,来自23 条Barremian Aptian Albian     

松辽盆地白垩系的密集段及海水进侵的新证

在总结松辽盆地白恶系层地层特征的基础上，阐述了密集段的地质学和地球物理学标志，经分析，大多数重要反射与密集段相关而并非是层序边界，根据扫描电镜分析结果，在密集段中首次发现了钙质超微化石，为区内白垩纪海水进侵的提供了新的证据，由稳定同位素分析，密集段形成了缺氧，相对可容纳空间最大及水体最深时期。