山东大汶口盆地石盐地球化学特征及其成因

白垩纪晚期-第三纪早期喜马拉雅期运动在中国东部形成一系列的内陆断陷含盐盆地,其中不少是中国的主力油气盆地。山东大汶口盆地是该时期山东地区西部最大的沉积赋矿盆地,也是中国东部发现的唯一含钾盐的盆地,盆地中富含石膏、岩盐、钾盐、自然硫等蒸发岩型矿产资源。大汶口盆地具有东向洼地、满庄-大西牛洼地两个沉降中心。本研究即通过满庄-大西牛洼地附近的钻孔,首次对山东大汶口盆地石盐地球化学特征进行了包括溴含量在内的系统分析,同时分析了石膏夹层的硫同位素。山东大汶口盆地石盐的溴含量在(3～19)×10^-6之间,硫同位素在14.7‰～35.7‰之间,这些分析结果都揭示山东大汶口盆地石盐为内陆盐湖成因。     

邯邢地区古近纪古气候环境演变研究

邯邢地区位于河北省南部,太行山脉南段东麓,华北平原西部边缘。区内古近纪地层广泛分布于太行山山前断裂带以东平原深覆盖区的几个凹陷之中,发育齐全,沉积厚度可观,西部山区及低山丘陵区缺失。通过邯邢地区岩性特征、古植被类型、微体古生物和孢粉分析等,对古近纪的不同时期古气候环境的演变进行了分析研究。     

昌都—兰坪—呵叻成盐带白垩纪成盐成钾过程

以昌都—兰坪—思茅盆地及呵叻盆地含盐带盐类沉积为研究对象,在分析总结前人研究成果的基础上,通过系统的大地构造学、矿床学、地球化学等研究方法,总结和研究了该区含钾蒸发岩矿床的矿床特征,提出了新的成矿模式。研究表明,兰坪—思茅盆地和呵叻盆地的含钾蒸发岩矿床为"海源陆相"成因,即在陆相环境下与海水的变异有关。该矿床缺失正常海水蒸发浓缩而形成的硫酸盐沉积,同时,矿床中少量菱镁矿等自生矿物的出现无法用正常海水蒸发理论解释。矿床中少量溢晶石等矿物的出现预示着该矿床富钙。兰坪—思茅盆地内广泛发育了白垩纪蒸发岩系(勐野井组或云龙组),江城地区甚至沉积了小型钾盐矿床。同位素和微量元素的研究表明,该区蒸发岩矿床为海相成因,Rb和Br的含量变化指示海水从北部兰坪侵入到呵叻。昌都及兰坪地区的白垩纪石膏硫、锶同位素研究表明,该区大套的硫酸盐沉积为海相成因,物源研究成果揭示思茅盆地的物源可能来自东羌塘地区,预示着昌都地区的硫酸盐沉积跟兰坪—思茅盆地的蒸发岩沉积具有同源性。通过上述研究,提出了多级盆地海水迁移变质成盐成钾模式。     

东濮凹陷盐湖盆地油气富集规律研究

国内外油气勘探实践表明,含盐盆地的油气富集和分布与盆地内沉积的盐岩密切相关。东濮凹陷是我国东部地区典型的含盐油气富集盆地,作者通过深入研究其地层层序特征及盐岩纵横向分布特点,进一步剖析了盐岩沉积的主要控制因素及其与生储盖层的关系,搞清了含盐盆地油气的分布和富集与盐岩的关系,指出无论在垂向上还是横向上,东濮凹陷盐岩一般都与暗色烃源岩共生,而且盐岩与同期沉积的砂岩表现为长消关系。研究认为盐岩可作为油气上盖或侧向遮挡,与源岩、储集层可组成良好的生储盖配置关系,利于油气富集区带的形成,对构造和隐蔽油气藏的形成都发挥了积极的作用,并指出与盐岩有关的文东北部和胡状集地区是下一步挖潜的有利勘探方向。研究成果也可为国内外同类含盐盆地的油气勘探提供一定的借鉴经验。     

内蒙古中部中侏罗统石拐群地油藏、煤藏情况与评价

内蒙古中部中侏罗统石拐群包括五当沟组和厂汉沟组,是一套厚度较大的湖相沉积建造,在石拐地区出露较全,厂汉沟组富含油页岩,石拐盆地发育丰厚的烃源岩。石拐盆地油气藏伴随侏罗系褶皱变形及地层抬升而上升运移,在盆地边缘及煤井中,多处见油气显示,特别是原油油苗的发现,标志着石拐盆地具备油气藏的形成与运移条件。     

广东省丹霞地貌的地质构造背景和分区研究

广东省共有丹霞地貌 67 处,分布在 22 个断陷盆地中,主要受古近纪―新近纪抬升区、5 条北东向深大断裂和 1 条东西向深断裂控制,地层层位以丹霞组和南雄群为主,岩性以砾岩、砂砾岩、砂岩为主。古近纪―新近纪地壳升降运动控制了丹霞地貌在区域上的总体分布,大致以 22.5°N 为界线,以北为抬升区,发育丹霞地貌,以南为沉降区,不发育丹霞地貌;晚更新世以来的地壳升降运动,造成不同地区丹霞地貌的数量和规模有所区别：粤北、粤东北为抬升区,发育数量多、规模较大;粤中为沉降区,发育数量少、规模较小。深大断裂控制断陷盆地的分布,从而控制丹霞地貌具体的发育位置。根据地质构造背景和丹霞地貌发育特征,可将广东省划分为 4 个丹霞地貌发育区：粤北区、粤中区、粤东北区和粤西区。     

苏北盆地洪泽凹陷古新世时期的古环境:来自蒸发岩的证据

第三纪古新世—始新世极热事件(PETM事件,Paleocene-Eocene Thermal Maximum),被认为是最类似于现今的温室效应时期。江苏省苏北盆地洪泽凹陷沉积了一套巨厚的古新世时期的蒸发岩,提供了该时期的陆地记录。蒸发岩对气候极为敏感,因此可以记录古代气候的信息。从苏北盆地洪泽凹陷钻孔中,通过SEM-EDS的方法识别出了无水芒硝和钙芒硝,这些暖相矿物的出现吻合第三纪古新世—始新世极热事件时期的极端高温环境;而苏打石的出现则表明该时期大致为现代大气三倍浓度的极高CO₂含量。     

江苏省苏北盆地洪泽凹陷古新世时期的古环境: 来自微体古生物学与蒸发岩的证据

第三纪古新世—始新世极热事件（PETM事件： Paleocene-Eocene Thermal Maximum）,被认为是最类似于现今的温室效应。江苏省苏北盆地洪泽凹陷沉积了一套巨厚的古新世时期的蒸发岩,提供了该时期的陆地记录。蒸发岩对气候极为敏感,因此可以记录古代气候的信息。本次研究从苏北盆地洪泽凹陷钻孔中,通过SEM-EDS的方法识别出了无水芒硝和钙芒硝,这些暖相矿物的出现吻合第三纪古新世—始新世极热事件时期的极端高温环境;而苏打石的出现则表明该时期大致为现代大气三倍浓度的极高CO2含量。     

新元古代—寒武纪硫同位素异常事件(Yudomski事件)的起源与结束

新元古代晚期—寒武纪早期是地球历史演化的关键时期,整个生物圈、大气圈和水圈在此期间都发生了巨大的变化,海水成分在其间也发生了明显的变化。而石盐流体包裹体恰恰记录了该时段海水主要离子成分的转变:海水成分从新元古代晚期的“文石海”,快速转化为寒武纪的“方解石海”;同时海水中的碳、锶、硫同位素都发生了剧烈的改变,其中海水硫酸根的硫同位素从新元古代冰期前的20‰左右,迅速升高到新元古代冰期后的35‰左右,甚至可以到45‰,海相蒸发岩沉积中的硫酸盐沉积(主要是石膏、硬石膏)则直接记录了当时海水中硫酸根的硫同位素变化。现有研究表明,新元古代晚期——寒武纪时期的海相蒸发岩沉积记录了当时海洋中存在着地质历史时期最大的硫同位素异常,即“Yudomski事件”。塔里木盆地的寒武纪早期、中期蒸发岩记录了“Yudomski事件”的硫同位素异常高值(35‰左右,甚至更高),表明这一起源于新元古代晚期的同位素异常事件持续到了寒武纪的早期和中期;塔里木盆地奥陶纪早期的蒸发岩、鄂尔多斯盆地奥陶纪中期蒸发岩和美国Williston盆地奥陶纪晚期地层的蒸发岩的硫同位素数据相似,都在+25‰左右则记录了较低的海洋硫同位素值,表明起源于新元古代冰期之后的“Yudomski事件”的硫同位素异常,持续到了寒武纪的中期,而结束于寒武纪的晚期。     

二连盆地努和廷铀矿床成矿机理探讨

该文在分析研究努和廷铀矿床主含矿层沉积充填序列和矿石特征的基础上,总结了该矿床铀成矿规律,初步建立了沉积成岩型铀成矿模式。研究认为,努和廷铀矿床属于典型的沉积成岩型铀矿床,其形成主要经历了晚白垩世二连期沉积成矿作用阶段和古近纪——新近纪成岩成矿作用阶段;该矿床产在晚白垩世形成的次级凹陷的沉积沉降中心,铀矿体严格受二连组湖泊扩张时期接受的湖泊沉积层控制;并提出今后应加强在二连组湖泊发育区的铀矿找矿工作。     

Middle Eocene‐Oligocene broken‐foreland evolution in the Andean Calchaqui Valley,NW Argentina: insights from stratigraphic,structural and provenance studies

Two end‐member models have been proposed for the Paleogene Andean foreland: a simple W‐E migrating foreland model and a broken‐foreland model. We present new stratigraphic, sedimentological and structural data from the Paleogene Quebrada de los Colorados (QLC) Formation, in the Eastern Cordillera, with which to test these two different models. Basin‐wide unconformities, growthstrata and changes in provenance indicate deposition of the QLC Formation in a tectonically active basin. Both west‐ and east‐vergent structures, rooted in the basement, controlled the deposition and distribution of the QLC Formation from the Middle Eocene to the Early Miocene. The provenance analysis indicates that the main source areas were basement blocks, like the Paleozoic Oire Eruptive Complex, uplifted during Paleogene shortening, and that delimits the eastern boundary of the present‐day intraorogenic Puna plateau. A comparison of the QLC sedimentary basin‐fill pattern with those of adjacent Paleogene basins in the Puna plateau and in the Santa Bárbara System highlights the presence of discrete depozones. These reflect the early compartmentalization of the foreland, rather than a stepwise advance of the deformation front of a thrust belt. The early Tertiary foreland of the southern central Andes is represented by a ca. 250‐km‐wide area comprising several deformation zones (Arizaro, Macón, Copalayo and Calchaquí) in which doubly vergent or asymmetric structures, rooted in the basement, were generated. Hence, classical foreland model is difficult to apply in this Paleogene basin; and our data and interpretation agree with a broken‐foreland model.     

The record of Himalayan erosion preserved in the sedimentary rocks of the Hatia Trough of the Bengal Basin and the Chittagong Hill Tracts,Bangladesh

The Cenozoic sedimentary succession of Bangladesh provides an archive of Himalayan erosion. However, its potential as an archive is currently hampered by a poor lithostratigaphic framework with limited age control. We focus on the Hatia Trough of the Bengal Basin and the adjacent fold belt of the Chittagong Hill Tracts which forms the outermost part of the west‐propagating Indo‐Burmese wedge. We present a basin‐wide seismic stratigraphic framework for the Neogene rocks, calibrated by biostratigraphy, which divides the succession into three seismically distinct and regionally correlatable Megasequences (MS). MS1 extends to NN15‐NN16 (ca. 2.5–3.9 Ma), MS2 to NN19‐NN20 (ca. 0.4–1.9 Ma) and MS3 to present day. Our seismic mapping, thermochronological analyses of detrital mineral grains, isotopic analyses of bulk rock, heavy mineral and petrographic data, show that the Neogene rocks of the Hatia Trough and Chittagong Hill Tracts are predominantly Himalayan‐derived, with a subordinate arc‐derived input possibly from the Paleogene IndoBurman Ranges as well as the Trans‐Himalaya. Our seismic data allow us to concur with previous work that suggests folding of the outer part of the west‐propagating wedge only commenced recently, within the last few million years. We suggest that it could have been the westward encroachment and final abutment of the Chittagong Hill Tracts fold belt onto the already‐uplifted Shillong Plateau that caused diversion of the palaeo‐Brahmaputra to the west of the plateau as the north‐east drainage route closed.     

Importance of inherited rift margin structures in the early North Alpine Foreland Basin, Switzerland

The earliest evolution of the North Alpine Foreland Basin in Switzerland was characterized by deposition in small, structurally partitioned sub-basins during the Late Cretaceous and Early Tertiary, rather than in a single, large foredeep. These sub-basins, which were probably located between old rift margin fault-blocks reactivated during Alpine compression, were incorporated into the thrust wedge during thin-skinned deformation. In eastern Switzerland, the most external sub-basins with respect to the orogenic wedge (North Helvetic Flysch and Blattengrat units) have at their base an unconformity attributed to flexural forebulge erosion. More internal sub-basins (Sardona and Prättigau units) contain a conformable succession from the underlying passive margin stage and are dominated by deep-water sedimentation. In western Switzerland, both external sub-basins, now found in the Helvetic Diablerets and Wildhorn nappes, and deep-water internal sub-basins (Höchst-Meilleret Flysch, Neisen Flysch, Tarentaise Flysch) preserve a well-developed basal unconformity. Comparison of the eastern and western Swiss transects shows important intrabasinal lateral variations to be present. The western Swiss area was a topographic high for much of the Late Cretaceous and Early Tertiary; this is demonstrated by the increased chronostratigraphic gap at the karstified basal unconformity surface in western Switzerland. The strata onlapping this unconformity young to the west, suggesting that drowning of the emergent area was delayed compared with the east. In addition, reactivation and uplift of the rift margin structures occurred earlier in western Switzerland compared with eastern Switzerland. There is therefore strong evidence for lateral topographic gradients in the early foreland basin caused by differential amounts of tectonic reactivation of rift margin structures. In the early foreland basin-fill, these lateral variations are as important in determining depositional patterns as strike-normal changes across the basin.     

Burial,Maturation, and Petroleum Generation History of the Arkoma Basin and Ouachita Foldbelt,Oklahoma and Arkansas

Removed overburden, burial, maturation, and petroleum generation analysis indicates that maturity in the Arkoma Basin and the Ouachita Foldbelt is explained effectively using simple burial models that account for the significant surface erosion that has occurred and assuming geothermal gradients similar to present-day gradients have been approximately constant through geologic time. Regional models, based on analysis at 115 well locations, indicate that from 5,000 to 15,000 ft (1.5–4.5 km) of section, differing with location from north to south and west to east, has been removed from the Arkoma Basin region, and as much as 25,000–40,000 ft (7.5–12 km) have been removed from areas of the Ouachita Foldbelt. Based on burial and thermal history reconstruction, increasing maturation from west to east across the basin is primarily the result of increasing overburden and subsequent surface erosion from west to east. The models predict most publicly available vitrinite reflectance data within a factor of 1.5 at two standard deviations. Comparison of model and measured reflectance-depth trends in six wells indicates that hydrothermal fluid movement should not have modified reflectance by more than approximately 20% in the center of the basin. Analysis indicates that most of the basin is overmature for oil production from intervals below the Spiro Sandstone, except to the north and northwest. Although thermal maturities are high, methane is stable throughout the basin. Except for the basal Arbuckle Group, all formations were thermally immature for oil generation prior to burial by the Mississippian and Morrowan in the Ouachita Foldbelt of Oklahoma and by the Atokan and Desmoinesian over most of the basin and study area. In the deeper part of the present basin, all strata entered and passed through the oil window during or within 10 My after Atokan time. Because no additional major quantities of hydrocarbons were generated after Atokan time, the hydrocarbons must have been emplaced and trapped during this brief time interval.     

Tertiary foreland sedimentation in the Southern Subalpine Chains, SE France: a geodynamic appraisal

Tertiary foreland sedimentation in SE France occurred along the western sidewall of the Alpine orogen during collision of the Apulian indentor with the European passive margin. A detailed reappraisal of the stratigraphy and structure of the Southern Subalpine Chains (SSC) in SE France shows that Tertiary depocentres of differing character developed progressively toward the foreland during ongoing SW-directed shortening. The geodynamic controls on each of four stages of basin development are evaluated using a flexural isostatic modelling package of thrust sheet emplacement and foreland basin formation. (1) The initial stage (mid to late Eocene) can be explained as a flexural basin that migrated toward the NW, closing off to the SW against the uplifting Maures–Esterel block. This broad, shallow basin can be reproduced in forward modelling by loading a lower lithospheric plate with an effective elastic thickness of 20 km. (2) The end of detectable flexural subsidence in the early Oligocene coincides with the emplacement of the internally derived Embrunais–Ubaye (E-U) nappes, which caused 11 km of SW-directed shortening in the underlying SSC. The lack of Oligocene flexural subsidence dictates that the E-U units were emplaced as gravitational nappes. Within the SSC, Oligocene sedimentation was restricted to small thrust-sheet-top basins recording mainly continental conditions and ongoing folding. Further west, Oligocene to Aquitanian NNW–SSE extension generated the Manosque half-graben as part of the European graben system that affected an area from the Gulf of Lion to the Rhine graben. (3) Following the Burdigalian breakup of the Gulf of Lion rift, a marine transgression migrated northward along the European graben system. Subsequent thermal subsidence allowed 1 km of marine sediments to be deposited across the Valensole and Manosque blocks, west of the active SSC thrust belt. (4) Mio-Pliocene conglomeratic deposits (2 km thick) were trapped within the Valensole basin by the uplifting Vaucluse block to the west and the advancing Alpine thrust sheets to the east. Late Pliocene thrusting of the SSC across the Valensole basin (approx. 10.5 km) can be linked along a Triassic detachment to the hinterland uplift of the Argentera basement massif.     

Compressional salt tectonics and synkinematic strata of the western Kuqa foreland basin,southern Tian Shan,China

The synkinematic strata of the Kuqa foreland basin record a rich history of Cenozoic reactivation of the Palaeozoic Tian Shan mountain belt. Here, we present new constraints on the history of deformation in the southern Tian Shan, based on an analysis of interactions between tectonics and sedimentation in the western Kuqa basin. We constructed six balanced cross‐sections of the basin, integrating surface geology, well data and a grid of seismic reflection profiles. These profiles show that the Qiulitage fold belt on the southern edge of the Kuqa basin developed by thin‐skinned compression salt tectonics. The structural styles have been influenced by two major factors: the nature of early‐formed diapirs and the basinward depositional limit of the Kumugeliemu salt. Several early diapirs developed in the western Kuqa basin, soon after salt deposition, which acted to localize the subsequent shortening. Where diapirs had low relief and a thick overburden they tended to tighten into salt domes 3000–7000 m in height. Conversely, where the original diapirs had higher relief and a thinner overburden they tended to evolve into salt nappes, with the northern flanks of the diapirs thrusting over their southern flanks. Salt was expelled forward, up dip along the mother salt layer, tended to accumulate at the distal pinch‐out of Kumugeliemu salt located at the Qiulitage fold belt. Furthermore, the synkinematic strata (6–8 km thick) of the Kuqa basin indicate that during the Cenozoic reactivation of the Tian Shan, shortening of the western Kuqa basin was mainly in the hinterland until the early Miocene. Then, compression spread simultaneously southwards to the Dawanqi anticline, the Qiulitage fold belt and the southernmost blind detachment fold at the end of Miocene. The western Kuqa basin has a shortening of ca. 23 km. We consider that ca. 9 km was consumed from the end of the Miocene (5.2/5.8 Ma) to the early Pleistocene (2.58 Ma) and another ca. 14 km have been absorbed since then. Thus, we obtain a ca. 3.4/2.8 mm year^?1 average shortening from 5.2/5.8 to 2.58 Ma, followed by a 60–90% increase in average shortening rate to ca. 5.4 mm year^?1 since 2.58 Ma. This suggests that the reactivation of the modern Tian Shan has been accelerating up to the present day.     

盐湖沉积改造与地下卤水成因——以库车和渤海湾盆地为例

2015年在新疆库车盆地发现高钾盐泉水,进一步为库车盆地地下钾盐找矿提供了线索。为探讨地下卤水成因,结合渤海湾盆地总结了受断裂活动控制发育的古盐湖底辟构造的盐湖沉积改造模式。控制盐体改造的断裂带及后期发育的断裂系为地下卤水的沟通和混合提供了空间和通道,从而影响地下卤水的矿化度和化学组分。氢氧同位素特征揭示：库车盆地高钾盐泉水的水体来源主要为当地大气降水,而钾的物质来源与古盐湖析盐后期浓缩卤水或地下固体钾盐的溶解有关;渤海湾盆地地层水则继承了古盐湖沉积卤水,后期接受水岩反应、浅层水体掺杂等改造作用,最终形成矿化度分布具有极大差异性的地层水。沉积盐体的“古凹今隆”决定着钾盐的沉积、分异变形改造和保存,隆起盐体的次级凹陷及陡坡一侧是高矿化度卤水储存及钾盐矿物沉积的有利部位,值得关注和深入研究。     

额济纳盆地地下水盐化特征及机理分析

运用水文地球化学方法,分析额济纳盆地不同含水层地下水盐化特征及其机理。结果表明:额济纳盆地地下水受水文地质条件的制约,潜水的盐化自沿河主要补给区到蒸发排泄区具有明显的分带性,由河流主要补给区向北和向东西两侧,至居延海,进素土海子和古日乃湖中心洼地地下水,地下水由淡水,逐渐过渡为微咸水、中度咸水及极度咸水、盐水;承压水属于微咸水。依据地下水中各离子含量的比值特征的分析结果,控制本区地下水盐化的主要因素为硅酸盐矿物溶解和蒸发沉积作用,硅酸盐矿物溶解主要发生在沿河的地下水补给区;蒸发沉积作用主要发生在地下水径流-排泄区。深层地下水埋藏较深,蒸发的作用大大减弱,因而含盐量少,水质较好。     

Contained turbidites used to track sea bed deformation and basin migration, Sorbas Basin, south-east Spain

ABSTRACT The mechanisms driving subsidence in late orogenic basins are often not easily resolved on account of later fault reactivation and a rapidly changing stress field. Contained turbidites in such basins provide a unique opportunity of monitoring sea bed deformation and evolving bathymetry and hence patterns of subsidence during basin filling. A variety of interpretations have been proposed to explain subsidence in Neogene basins in SE Spain, including extensional, strike‐slip and thrust top mechanisms. Ponded turbidite sheets on the floor of the Neogene Sorbas Basin (SE Spain) were deposited by sand‐bearing currents which ran into enclosed bathymetric deeps where they underwent rapid suspension collapse. The structure and distribution of these sheets (and the thick mudstone caps which overlie them) act as a proxy for the containing sea bed bathymetry at the time of deposition. An analysis of the sheet architecture helps identify a trough‐axial zone of syndepositional faulting and reveals a westwards stepping of the ponding depocentre with time. Fault breaks at the sea bed influenced the position of flow arrest and the distribution of sandstone beds on the basin floor. Westward stepping of the deeper bathymetry was episodic and probably controlled by transverse faults. Re‐locations of the depocentre were accompanied by the destabilization of carbonate sand stores on the margins of the basin, resulting in the repeated emplacement of large‐volume carbonate megabeds and calciturbidites. The fill to the Sorbas Basin was shingled by the onset of compression in the east attributed to transfer of slip between intersecting strike‐slip fault strands. A sinistral fault (a splay of the Carboneras Fault System) propagated through the evolving basin fill from the east as the eastern part of the basin became inverted and the locus of subsidence migrated into the Tabernas area 20 km area to the west. The sedimentological analysis of the basin fill helps see through a late dextral overprint which ultimately juxtaposed basement rocks to the south against the inverted and upended basin, along a late slip‐modified unconformity. Conventional palaeostress analysis of fractures along the basin margin fails to see past this late dextral shearing event. Basin migration parallel to the E–W‐orientated basin axis, slip‐reversal (sinistral to dextral) and the active involvement of strike‐slip faults are now identified as important aspects of the evolution of the Sorbas Basin during the latestTortonian.