准噶尔盆地中侏罗统西山窑组与头屯河组间不整合面特征及其油气勘探意义

准噶尔盆地侏罗系顶、底及其内部不整合广泛发育,其中中侏罗统下部西山窑组和上部头屯河组之间的角度不整合尤为清楚。它表现为区域性不整合,沉积间断时限达4～10 Ma,剥蚀厚度达100～340 m。该不整合“面”的结构由不整合面之上的砂岩、不整合面之下的风化粘土层和半风化岩石组成,以砂岩-泥岩-砂岩的组合为主,平均厚度达70～90 m。依靠风化粘土层,不整合面之上头屯河组的砂岩形成了地层超覆圈闭,不整合面之下西山窑组的砂岩形成了地层削截不整合遮挡圈闭。油气勘探实践表明：该不整合面上、下是油气聚集的重要场所;该不整合面的后期掀斜演变对油气聚集和调整再分配产生了重要影响。     

藏北羌塘奥陶纪平行不整合面的厘定及其构造意义

西藏羌塘块体有无变质基底、其前新生代构造属性与演化过程是长期争论的议题。本文报道南羌塘块体北部,中、上奥陶统塔石山组底砾岩平行不整合于浅变质中厚层石英砂岩夹薄层泥灰岩之上。近600粒碎屑锆石测年结果表明浅变质石英砂岩的最大沉积年龄为527±7Ma,300余粒碎屑锆石测年结果表明塔石山组底部石英砂岩的最大沉积年龄为471±6Ma。不整合面上、下石英砂岩最大沉积年龄之差达56Myr,表明这两套石英砂岩之间存在明显的沉积间断,证实了该平行不整合面的时代为奥陶纪早期。另一独立的证据是在邻区发现了早奥陶世花岗岩类岩石(471~477Ma)侵位于该浅变质石英岩,因此将不整合面之下的浅变质石英岩暂命名为荣玛组,归入寒武系地层。阴极发光与年代学研究进一步表明不整合面之上的碎屑锆石主要来源于在"泛非"运动晚期形成的结晶岩,为近源锆石,表明"泛非运动"晚期所形成的结晶岩在奥陶纪早期就已隆升,遭受剥蚀,为区内中上奥陶统沉积岩的形成提供物质来源。该奥陶纪平行不整合面的发现,表明南羌塘块体与喜马拉雅、拉萨等块体相似,同属冈瓦纳大陆体系。南、北羌塘早古生代地层系统之间的显著差异表明在寒武-奥陶纪之交,南、北羌塘块体就已被古大洋盆分隔开,开始各自独立演化。     

北京西山下苇甸地区青白口系长龙山组沉积相及层序地层研究*

北京西山下苇甸地区出露良好的青白口系长龙山组,笔者通过实测野外露头剖面以及岩石薄片镜下鉴定,对该组下部沉积相及层序地层进行研究,并对沉积环境演化进行分析。识别出长龙山组下部8种岩石类型有含砾砂岩、羽状交错层理砂岩、丘状交错层理砂岩、波状层理粉砂岩、脉状层理粉砂岩、透镜状层理粉砂岩、碳质泥岩以及水平层理泥岩;并识别出辫状河道、潮坪(潮道)、潮下浅水及潮下深水等沉积相类型,建立该区辫状河—滨岸潮坪沉积模式。进而通过识别长龙山组与其下伏地层之间的区域不整合面和下切谷河道充填砂砾岩底面确定层序界面。其中,初始海泛面以每个砂体之上覆盖的细粒沉积的底面为代表,最大海泛面以厚层碳质泥岩及水平层理泥岩的底面为代表。依据这些关键层序地层界面,将该区长龙山组下部划分为3个层序,每个层序内部进一步划分为低位体系域、海侵体系域以及高位体系域。综合分析表明,京西的长龙山组发育于由燕辽裂陷槽转为华北稳定克拉通的过渡期。     

鄂尔多斯盆地东北部下石盒子组盒8段辫状河三角洲沉积特征

中二叠统下石盒子组盒8段为鄂尔多斯盆地东北部天然气的主产层位,其储集砂体受控于沉积相带的展布。通过对野外露头、岩心及测井曲线等综合分析,笔者认为研究区内主要以发育辫状河三角洲为特征,并对其沉积特征、影响其形成和发育的机理,以及岩相和砂体的展布特征进行深入研究。认为该区盒8段三角洲为辫状河-浅水型湖泊三角洲,在三角洲平原相区储集砂体为分流河道沉积;而在三角洲前缘相区则为水下分流河道沉积,河口坝、席状砂及远砂坝等沉积微相不发育。     

辽宁兴城地区前寒武纪地层序列和不整合

辽宁兴城地区位于华北克拉通中、新元古代燕山裂陷槽盆地（燕辽海盆）的东南边缘,地层序列和沉积特征与同属盆地边缘区的河北滦县、北京南口、以及太行山区等地类似。研究区新太古代花岗岩之上沉积了长城系（常州沟组、串岭沟组、团山子组、大红峪组）,蓟县系（高于庄组、杨庄组、雾迷山组）,以及青白口系（长龙山组、景儿峪组）。与天津蓟县中、新元古界标准剖面相比,本区地层厚度较薄、长城系碳酸盐岩较少、碎屑物粒度较粗、部分层位（铁岭组、洪水庄组、下马岭组？）缺失,几大沉积层序的底界超覆明显,体现了典型的古陆边缘特征。中元古界常州沟组至团山子组为一套局限分布的滨、浅海相海进至海退旋回沉积,常州沟组滨海相砂岩与下伏新太古代花岗岩沉积接触;大红峪组沉积时期广泛海侵,以石英砂岩和粉砂质页岩为主,下部发育复成分角砾岩和石英砂岩质砾岩,与下伏地质体有沉积接触（非整合）、角度不整合、微角度不整合、岩溶不整合等多种接触关系,说明大红峪组沉积之前发生过沉积间断和地层褶皱变形,“兴城运动”所指的不整合并非单纯的海进超覆成因;蓟县系高于庄组下部为一套海侵陆源碎屑岩序列,不整合在大红峪组和新太古代花岗岩之上,中、上部为碳酸盐岩台地沉积;蓟县系杨庄组和雾迷山组总体为碳酸盐岩,仅含少量陆源碎屑成分或薄层;新元古界青白口系长龙山组为又一套陆源碎屑岩海进序列,平行不整合在蓟县系雾迷山组或待建系下马岭组？角砾状含燧石白云质灰岩之上,指示了芹峪上升和蔚县上升影响期间的岩溶平原发育历史;寒武系昌平组角砾状白云质灰岩平行不整合在景儿峪组中、薄层白云质灰岩之上。上述不整合及地层建造特征还说明山海关古陆长期存在并对辽西南部的沉积古地理有明显影响。此外,大红峪组的沉积在区内具有承前启后的意义,自大红峪组沉积开始本区与燕辽海盆完全连通,整个盆地的演化也从强烈断陷向稳定沉降转变。     

Coupled U–Pb–Hf of detrital zircons of Cambrian sandstones from Morocco and Sardinia: Implications for provenance and Precambrian crustal evolution of North Africa

U–Pb–Hf of detrital zircons from diverse Cambrian units in Morocco and Sardinia were investigated in order to clarify the sandstone provenance and how it evolved with time, to assess whether the detrital spectra mirror basement crustal composition and whether they are a reliable pointer on the ancestry of peri-Gondwanan terranes. Coupled with Hf isotopes, the detrital age spectra allow a unique perspective on crustal growth and recycling in North Africa, much of which is concealed below Phanerozoic sediments.In Morocco, the detrital signal of Lower Cambrian arkose records local crustal evolution dominated by Ediacaran (0.54–0.63 Ga) and Late-Paleoproterozoic (1.9–2.2 Ga; Eburnian) igneous activity. A preponderance of the Neoproterozoic detrital zircons possess positive ε_Hf(t) values and their respective Hf model ages (T_DM) concentrate at 1.15 Ga. In contrast, rather than by Ediacaran, the Neoproterozoic detrital signal from the Moroccan Middle Cambrian quartz-rich sandstone is dominated by Cryogenian-aged detrital zircons peaking at 0.65 Ga alongside a noteworthy early Tonian (0.95 Ga) peak; a few Stenian-age (1.0–1.1 Ga) detrital zircons are also distinguished. The majority of the Neoproterozoic zircons displays negative ε_Hf(t), indicating the provenance migrated onto distal Pan-African terranes dominated by crustal reworking. Terranes such as the Tuareg Shield were a likely provenance. The detrital signal of quartz–arenites from the Lower and Middle Cambrian of SW Sardinia resembles the Moroccan Middle Cambrian, but 1.0–1.1 Ga as well as ~ 2.5 Ga detrital zircons are more common. Therefore, Cambrian Sardinia may have been fed from different sources possibly located farther to the east along the north Gondwana margin. 1.0–1.1 Ga detrital zircons abundant in Sardinia generally display negative ε_Hf(t) values while 0.99–0.95 Ga detrital zircons (abundant in Morocco) possess positive ε_Hf(t), attesting for two petrologically-different Grenvillian sources. A paucity of detrital zircons younger than 0.6 Ga is a remarkable feature of the detrital spectra of the Moroccan and Sardinian quartz-rich sandstones. It indicates that late Cadomian orogens fringing the northern margin of North Africa were low-lying by the time the Cambrian platform was deposited. About a quarter of the Neoproterozoic-aged detrital zircons in the quartz-rich sandstones of Morocco (and a double proportion in Sardinia) display positive ε_Hf(t) values indicating considerable juvenile crust addition in North Africa, likely via island arc magmatism. A substantial fraction of the remaining Neoproterozoic zircons which possess negative ε_Hf(t) values bears evidence for mixing of old crust with juvenile magmas, implying crustal growth in an Andean-type setting was also significant in this region.     

Forced regressive shoreface sandstone from Himalayan foreland: Implications to early Himalayan tectonic evolution

Sedimentology and sequence stratigraphic analysis of the ∼ 31 Ma old marker White sandstone unit from the Subathu Sub-basin, NW Himalayan foreland, suggest it to be a forced regressive wedge (FRW) formed during the transition from the marine Subathu Formation to the continental Dagshai Formation. The FRW is bounded between the “Surf diastem” below and type 1 unconformity at the top and differs from RSME (regressive surface of marine erosion, occurring below) bounded FRWs described from other classical coastal/foreland settings. Correct identification of bounding surfaces of a FRW has an important implication to the estimation of rate of relative sea-level (RSL) fall. A faster rate of RSL fall, higher than the sedimentation rate, has been postulated for the erosion of the lower shoreface and RSME. Using the logged thickness of the Subathu/Dagshai transition zone including the White sandstone (bounded between the “Surf diastem” and unconformity), available chronology and eustatic sea-level fall (0.023 mm/year at 31 Ma), a higher RSL fall than the sedimentation rate (0.07 mm/year) has been inferred during the deposition of the White sandstone. Petrography of sandstones and their Sr and Nd isotopic compositions indicate a major provenance switch-over from dominant mafic/ultramafic to metamorphic source from White sandstone (∼ 31 Ma) onwards attesting the link between hinterland tectonics, provenance and forced regression. The provenance switch-over at 31 Ma was earlier inferred to be driven by proto-Himalayan thrust propagation in the foreland. Using a simple isostatic model, on the contrary, a mechanism of accelerated surface uplift (at a rate of > 0.10-0.15 mm/year) is suggested for both provenance change and forced regression.     

Late Ordovician stratigraphy,zircon provenance and tectonics,Lachlan Fold Belt,southeastern Australia

Ordovician quartz turbidites of the Lachlan Fold Belt in southeastern Australia accumulated in a marginal sea and overlapped an adjoining island arc (Molong volcanic province) developed adjacent to eastern Gondwana. The turbidite succession in the Shoalhaven River Gorge, in the southern highlands of New South Wales, has abundant outcrop and graptolite sites. The succession consists of, from the base up, a unit of mainly thick‐bedded turbidites (undifferentiated Adaminaby Group), a unit with conspicuous bedded chert (Numeralla Chert), a unit with common thin‐bedded turbidites (Bumballa Formation (new name)) and a unit of black shale (Warbisco Shale). Coarse to very coarse sandstone in the Bumballa Formation is rich in quartz and similar to sandstone in the undifferentiated Adaminaby Group. Detrital zircons from sandstone in the Bumballa Formation, and from sandstone at a similar stratigraphic level from the upper Adaminaby Group of the Genoa River area in eastern Victoria, include grains as young as 453–473 Ma, slightly older than the stratigraphic ages.The dominant detrital ages are in the interval 500–700 Ma (Pacific Gondwana component) with a lessor concentration of Grenville ages (1000–1300 Ma). This pattern resembles other Ordovician sandstones from the Lachlan Fold Belt and also occurs in Triassic sandstones and Quaternary sands from eastern Australia. The Upper Ordovician succession is predominantly fine grained, which reflects reduced clastic inputs from the source in the Middle Cambrian to earliest Ordovician Ross‐Delamerian Fold Belts that developed along the eastern active margin of Gondwana. Development of subduction zones in the Late Ordovician marginal sea are considered to be mainly responsible for the diversion of sediment and the resulting reduction in the supply of terrigenous sand to the island arc and eastern part of the marginal sea.     

Characterization of heterogeneity of the Shajara reservoirs of the Shajara formation of the Permo-Carboniferous Unayzah group

Representative sandstone samples were collected from the surface-type section of the Shajara Formation of the Permo-Carboniferous Unayzah Group for reservoir characterization through fractal dimension investigation. Two models based on mercury intrusion technique were employed to represent the pores characteristics of these sandstones. The results show that realistic dimensions and outstanding fractal features of porous structures in Shajara sandstones, when these materials are correlated by thermodynamic model and 3-D fractal model of mercury intrusion. On the basis of sub-Unayzah unconformity, sub-Middle Shajara local unconformity, mudstone of the Middle Shajara and sub-Khuff unconformity, the three porous and permeable sandstone units of Shajara Formation were treated separately and classified here into three fractal dimension units. The units from base to top are: Lower Shajara Fractal Dimension Unit, Middle Shajara Fractal Dimension Unit, and Upper Shajara Fractal Dimension Unit. The thermodynamic model and 3-D fractal model were effectively used to characterize the porous structures of Shajara sandstones in logical and quantitative way.     

Sequence stacking patterns in the Western Canada foredeep: influence of tectonics, sediment loading and eustasy on deposition of the Upper Cretaceous Kaskapau and Cardium Formations

The Kaskapau and Cardium Formations span Late Cenomanian to Early Coniacian time and were deposited on a low‐gradient foredeep ramp. The studied portion of the Kaskapau Formation spans ca 3·5 Myr and forms a mudstone‐dominated wedge thinning from 700 to <50 m from SW to NE over ca 300 km. In contrast, the Cardium Formation spans about 2·1 Myr, is about 100 m thick, sandstone‐rich and broadly tabular. The Kaskapau and Cardium Formations are divided, respectively, into 28 and nine allomembers, each bounded by marine flooding surfaces. Kaskapau allomembers 1 to 7 show about 200 km of offlap from the forebulge, accompanied by progradation of thin sandstones from the eroded forebulge crest. In contrast, Kaskapau allomembers 8 to 28 and Cardium allomembers C1 to C9 show overall onlap onto the forebulge of about 350 km, and contain no forebulge‐derived sandstones. This broad pattern is interpreted as recording a latest Cenomanian pulse of tectonic loading which led to shoreline back‐step in the proximal foredeep and coeval uplift of the forebulge, leading to erosion. The advance of the sediment wedge after Kaskapau allomember 7 is attributed primarily to the isostatic effect of a distributed sediment load; the advance of the orogenic wedge had a subordinate effect on subsidence of the forebulge. For Kaskapau allomembers 1 to 6, isopachs trend north to south, suggesting a load directly to the west; allomembers 7 to 28 show an abrupt rotation of isopachs to NW–SE, suggesting that the load shifted several hundred kilometres to the south. This re‐orientation might be related to a change from an approximately orthogonal to a dextral transpressive stress regime. Within the longer‐term offlap–onlap cycle recorded by the Kaskapau and Cardium Formations, individual allomembers are grouped into packages reflecting higher‐frequency onlap–offlap cycles, each spanning ca 0·5 to 0·7 Myr. Offlap from the forebulge tends to be accompanied by more pronounced transgression in the foredeep, whereas onlap onto the forebulge is accompanied by progradation of tongues of shoreface sandstone. This relationship suggests that changes in deformation rate in the orogenic wedge modulated proximal subsidence rate, enhancing or suppressing shoreline progradation, and also causing subtle uplift or subsidence of the forebulge region. Wedge‐shaped allomembers in the Kaskapau Formation contain shoreface sandstone and conglomerate that prograded, respectively, <40 and <25 km from the preserved basin margin; progradation of coarse clastics was limited by rapid flexural subsidence. Tabular allomembers of the Cardium Formation imply a low flexural subsidence rate and contain sandy and conglomeratic shoreface deposits that prograded up to ca 180 km from the preserved basin margin. This relationship suggests that low rates of flexural subsidence promoted steeper alluvial gradients, more vigorous gravel transport and more extensive shoreface progradation. Overall, observed stratal geometry and facies distribution is explained readily in terms of current elastic flexural models. Most shoreface sandstones in the proximal foredeep show evidence of forced regression. Eustasy provides the most plausible explanation for relative sea‐level rise–fall cycles on the 125 kyr allomember timescale. Geometric relationships suggest eustatic oscillations of about 10 m. Forced regressive shoreface development was suppressed during Kaskapau allomembers 1 to 10 when the rate of flexural subsidence was at its highest.     

Seismic tectono-stratigraphy of fluvio-deltaic to deep marine Miocene silicoclastic hydrocarbon reservoir systems in the Gulf of Hammamet,northeastern Tunisia

Most of hydrocarbon accumulations within the Gulf of Hammamet foreland basins in eastern Tunisia are reservoired within the Upper Miocene Birsa and Saouaf sandstones. It is the case of Birsa, Tazarka, Oudna, Baraka, Maamoura, Cosmos and Yasmine fields. These sandstones constitute oil and gas fields located on folded and faulted horst anticline highs and described as varying from shoreface to shallow marine and typically exhibit excellent reservoir quality of 30 to 35% porosity and good permeability from 500 to 1100 md. In addition, the fracturing of faults enhanced their reservoir quality potential. However, due to the lack of seismic stratigraphic studies to highlight depositional environment reservoir characterization and distribution, petroleum exploration faces structural and stratigraphic trap types and remains on targeting only high fold closures with limited reserve volumes of hydrocarbons. As an example of the Birsa concession case, syn-sedimentary tectonic structuring and geodynamic evolution during Middle to Upper Miocene Birsa reservoir sequences have guided the distribution of depositional environment of sandstone channel systems around horst and grabens by E-W, NE-SW and N-S strike slip flower faults controlling the subsidence distribution combined with the eustatic sea level variations. Seismic sequence stratigraphy study of Miocene Birsa reservoir horizons, based on the analysis and interpretations of E-W and N-S 3D selected regional lines that were compared and correlated to outcrops and calibrated by well data, permitted to highlight the basin configuration and sequence deposit nature and distribution. Sedimentary infilling of the basin from Langhian Ain Ghrab carbonate to Serravallian Tortonian Birsa and Saouaf sandstone and shale formations is organized in four third-order seismic sequences, limited by regional erosional toplap, onlap and downlap unconformity surfaces and by remarkable chronostratigraphic horizons of forced and normal erosive lowstand and highstand system tracts separated by transgressive and maximum flooding surfaces. Reconstructed sedimentary paleo-environment distribution vary from deltaic fluvial proximal deposits in the northern part of the high central Birsa horst to a delta front and prodelta coastal and shelf shore face and shore line channelized deposits in the surrounding borders of grabens. Distal deposits seem to be distributed from upper to lower slope fans and probably to the basin floor on the flanks of the subsiding grabens. Synthetic predictive paleogeographic depositional reservoir fairway map distribution of Lower, Middle and Upper Birsa sandstone reservoirs highlights four main domains of channelized superposed and shifted reservoirs to explore.     

Early Cambrian and latest Proterozoic stratigraphy,Desert Syncline,southern Georgina Basin

In the Desert Syncline of the southern Georgina Basin there is an Early and Middle Cambrian sequence unconformably overlying late Proterozoic sediments. Stratigraphic drilling and subsequent palaeontological studies have allowed the documentation of the sequence across the Proterozoic‐Cambrian unconformity. Earliest Cambrian green shales are bioturbated and contain distinctive acritarchs. These are overlain, probably unconformably, by sandstone with Diplocraterion burrows, in turn succeeded by archaeocyathan dolostone. Ordian and Templetonian (Middle Cambrian) shales and carbonates unconformably overlie the Early Cambrian sequence. The stratigraphic sequence is very similar to that in the Amadeus Basin and the Adelaide Geosyncline.     

四川盆地东北部中二叠统层序地层特征

本文以野外露头观察及录井、测井、地震、古生物等资料为基础,通过岩石地层、测井地层及生物地层等的综合分析,在四川盆地东北部中二叠统地层中识别出4种类型的层序界面:隆升侵蚀不整合面、暴露层序不整合面、海侵上超不整合面及岩性岩相转换面。划分了3个三级层序:SQ1对应梁山组和栖霞组,时限约7Ma;SQ2对应茅口组一段,时限约3Ma;SQ3对应茅口组二段-三段,时限约5Ma。三级层序的平均时限约5Ma。同时,分析了层序对储层的控制作用,其主要体现在两个方面:层序控制了沉积相,影响了储层原生孔隙的发育;碳酸盐岩的发育受三级层序海平面升降控制,优质储层明显受控于海退半旋回。     

湖南邵阳地区茅口期晚期重力流沉积的发现及意义*

湖南邵阳市邵阳大道两侧出露的龙潭组下段(中二叠世茅口期晚期)发育一套地质特征典型、沉积序列明显的重力流沉积。重力流沉积以块状砂岩、粉砂岩及泥岩互层为主,砂岩底面发育有重荷模、槽模、工具痕及冲刷充填构造,砂岩内部有块状层理、平行层理、包卷层理及粒序层理,互层的泥岩中见类似于古网迹的痕迹化石。可识别出砂质碎屑流、浊流与滑塌沉积。剖面下部含泥砾块状砂岩发育,剖面中上部以发育薄到中厚层砂岩、粉砂岩与泥岩互层为特点。根据重力流沉积物特征及其垂向序列特征,建立了重力流沉积模式,将海底扇划分出内扇、中扇与外扇。通过与附近的短陂桥矿区的龙潭组下段沉积特征进行对比研究,结合华南地区岩相古地理特征,认为位于华南盆地范围的邵阳地区,在中二叠世茅口期晚期(龙潭组下段)发育的重力流沉积,可能意味着华南盆地在扬子陆块和华夏陆块之间的深大断裂在中二叠世末期曾经发生拉张,形成裂谷盆地。     

塔里木盆地寒武纪构造-沉积环境与原型盆地演化

寒武系是塔里木盆地当前油气增储上产的重点层系,恢复寒武纪的盆地原型是油气勘探的重要基础。利用最新的钻井、地震及露头资料,以沉积相为研究实体,将盆地充填与周缘构造演化相结合,由点→线→面进行分析,恢复了塔里木盆地寒武纪不同时期的构造-沉积环境,并建立了相应的盆地充填演化模式。塔里木盆地寒武纪经历了一次完整的海侵-海退旋回,包括早寒武世早期快速海侵→中寒武世海退、晚寒武世缓慢海侵→寒武纪末海退两个次级旋回,分别对应沉积演化的2个阶段：塔西克拉通内坳陷早寒武世的碎屑滨岸-陆棚相→局限台地相→中寒武世的蒸发台地相,晚寒武世的局限台地相→寒武纪末期的台地暴露不整合;塔东克拉通边缘坳陷为深水盆地相,经历了硅质泥岩→泥岩与灰岩薄互层→碳酸盐岩的岩相演化。寒武纪塔里木原型盆地特征及演化主要受控于Rodinia超大陆的裂解,其构造-沉积格局经历了由震旦纪末的南北分异格局向中-晚寒武世的东西分异格局的演变。     

Depositional facies,environments and sequence stratigraphic interpretation of the Middle Triassic–Lower Cretaceous (pre-Late Albian) succession in Arif El-Naga anticline,northeast Sinai,Egypt

The Middle Triassic–Lower Cretaceous (pre-Late Albian) succession of Arif El-Naga anticline comprises various distinctive facies and environments that are connected with eustatic relative sea-level changes, local/regional tectonism, variable sediment influx and base-level changes. It displays six unconformity-bounded depositional sequences. The Triassic deposits are divided into a lower clastic facies (early Middle Triassic sequence) and an upper carbonate unit (late Middle- and latest Middle/early Late Triassic sequences). The early Middle Triassic sequence consists of sandstone with shale/mudstone interbeds that formed under variable regimes, ranging from braided fluvial, lower shoreface to beach foreshore. The marine part of this sequence marks retrogradational and progradational parasequences of transgressive- and highstand systems tract deposits respectively. Deposition has taken place under warm semi-arid climate and a steady supply of clastics. The late Middle- and latest Middle/early Late Triassic sequences are carbonate facies developed on an extensive shallow marine shelf under dry-warm climate. The late Middle Triassic sequence includes retrogradational shallow subtidal oyster rudstone and progradational lower intertidal lime-mudstone parasequences that define the transgressive- and highstand systems tracts respectively. It terminates with upper intertidal oncolitic packstone with bored upper surface. The next latest Middle/early Late Triassic sequence is marked by lime-mudstone, packstone/grainstone and algal stromatolitic bindstone with minor shale/mudstone. These lower intertidal/shallow subtidal deposits of a transgressive-systems tract are followed upward by progradational highstand lower intertidal lime-mudstone deposits. The overlying Jurassic deposits encompass two different sequences. The Lower Jurassic sequence is made up of intercalating lower intertidal lime-mudstone and wave-dominated beach foreshore sandstone which formed during a short period of rising sea-level with a relative increase in clastic supply. The Middle-Upper Jurassic sequence is represented by cycles of cross-bedded sandstone topped with thin mudstone that accumulated by northerly flowing braided-streams accompanying regional uplift of the Arabo–Nubian shield. It is succeeded by another regressive fluvial sequence of Early Cretaceous age due to a major eustatic sea-level fall. The Lower Cretaceous sequence is dominated by sandy braided-river deposits with minor overbank fines and basal debris flow conglomerate.     

Redefinition of Early Mesoproterozoic (1800–1600 Ma) stratigraphy in the northern Kongling area,China: The nucleus of Yangtze Craton and its tectonic significance

The Wujiatai Formation, which is well exposed in Huangjiatai-Xichahe region of the northern Kongling area of central Yangtze Craton, is a suite of epimetamorphic conglomerates to pebbly sandstones to fine sandstone-dolostones deposited in littoral-carbonate platform facies. The formation has angular unconformity contacts with both the overlying Neoproterozoic Nantuo Formation and the underlying Paleoproterozoic Huanglianghe Formation complex. Detrital zircons from metafine sandstones of the lower Wujiatai Formation have ages ranging from 3377–1828 Ma, with the youngest zircons dating to about 1828 Ma. In addition, whole-rock Pb-Pb isochron ages from dolostones in the upper Wujiatai Formation yield an age of 1718±230 Ma. These dates constrain the depositional age of the Wujiatai Formation between 1800 Ma and 1600 Ma. These are the earliest Mesoproterozoic sedimentary records reported in the Kongling region, and fill the gaps in Early Mesoproterozoic stratigraphy in Yangtze Craton. Histograms of detrital zircon ages for the Wujiatai Formation reveal four major peaks at 2039 Ma, 2691 Ma, 2966 Ma and 3377 Ma, which is consistent with the ages of the basement rocks that underlie the center of Yangtze Craton, indicating that sediment provenance is mainly from the Kongling complex. The lower Wujiatai Formation mainly consists of clastic rocks, whereas the upper Wujiatai Formation consists of dolostones. This stratigraphic change implies a deepening sequence in an expanding basin with an initial cratonic rifting tectonic setting, corresponding to the initial breakup of the Columbia supercontinent in Yangtze Craton.© 2019 China Geology Editorial Office.     

塔里木盆地天山南缘区带古近系苏维依组沉积储层研究

根据钻井、测井与分析测试等资料,研究了塔里木盆地天山南缘区块北带苏维依组的沉积相带和储层特征。苏维依组分为下部底砂岩段和上部的膏泥岩段,在研究区主要发育辫状河三角洲和湖泊沉积体系。本区储层多为粉砂岩、细砂岩、中砂岩和含砾砂岩,主要岩石类型为长石石英砂岩和岩屑长石砂岩。孔隙类型主要是原生粒间孔、溶蚀孔,还有裂缝和微孔隙等。底砂岩段储层物性较好,总体属于中孔-中、低渗储层,非均质性较强,其中以三角洲前缘的分流河道和席状砂微相砂体物性最好。影响研究区储层物性的主要因素有沉积相带、成岩作用等,压实作用、溶蚀作用和胶结作用是对储层物性影响最大的成岩作用。