The Structure of the Sedimentary Cover of the Kandalaksha Gulf,White Sea,from Seismoacoustic Data

The geological structure of water areas adjacent to the White Sea biological research station of Moscow State University (Rugozero Bay and Great Salma Strait; both are parts of the Kandalaksha Gulf, White Sea) was studied for the first time based on the seismoacoustic data. The morphology of the top of the Achaean basement, the structure of the Quaternary sedimentary cover, and the bottom topography were investigated. The sequence of glacial deposits dated back to the last glaciation and the compound sequence consisting of glaciolacustrine, glacial-marine, and marine sediments are distinguished. The spatial locations and changes of their thicknesses are considered. It is shown that the recent bottom topography is controlled by predominantly NW- and NE-striking faults that run through the entire sedimentary sequence, including the Holocene sediments.     

Crust and upper mantle structure under the baltic shield and barents sea from the dispersion of rayleigh waves

The dispersion of fundamental-mode Rayleigh waves for several paths in Fennoscandia is consistent with the geological setting for the Baltic shield. Additional dispersion data indicate that the Barents Sea is a shield as well. The dispersion under the Baltic Sea is similar to the north-central United States, suggesting the extension of the mantle shield structure beneath the continental Paleozoic sedimentary cover.     

The West Bornholm basin in the Baltic Sea: geological structure and Quaternary sediments

KÖgler, F.-C. & Larsen, B. 1979 03 01: The West Bornholm basin in the Baltic Sea: geological structure and Quaternary sediments. Boreas . Vol. 8, pp. 1–22. Oslo. ISSN 0300–9483.
The West Bornholm basin is an approx. 1000 km² subbasin of the Bornholm basin just north of Bornholm. The basin has been mapped by acoustic profiling and sampling of the sea floor. The basin is eroded down into Mesozoic sediments which are downfaulted between basement horsts in the Fennoscandian Border Zone. The development of the Quaternary morphology is illustrated by maps of the surface of the bedrock, the glacial landscape beneath the varved clays, the recent topography combined with isopach maps of late Glacial and Holocene formations. Quaternary formations are defined and described. The brown, very fine grained varved clay is deposited as a conformable cover on the substratum. It is probably deposited from suspensions carried in the whole water body, while turbidity currents were of minor importance. The recent sedimentary environment is an example of a restricted, but not totally anoxic basin. The recent sediment is chiefly mud rich in organic matter (ca. 4% C_org). According to a rough estimate, the long-term mean sedimentation rate of organic carbon is 6 g/m²/year.     

河北怀来地区ZK02孔第四系地层结构特征

研究第四系地层结构特征和沉积环境,不仅对掌握区域第四纪发展史和气候变化具有重要意义,还可为合理利用地质资源和防治地质灾害提供重要依据。以怀来地区ZK02孔揭露的地层特征为依据,分析第四系地质结构,探讨怀来地区第四系特殊的沉积环境演变。结果表明：海拔600 m以上的山间河流发育了较厚的第四系中、上更新统沉积物,且研究区第四系自下而上以河床-边滩相沉积环境为特征,表明新构造运动和气候变化控制了第四纪时期的沉积环境演变,特殊的地质环境塑造了特殊的第四系地层结构特征。     

中国晚新生代构造-沉积-古气候事件的地质记录

中国区域地质调查工作的重点正在转向大面积覆盖区为主的平原、盆地、草原、荒漠等地区，向深部三维调查拓展.第四纪松散沉积层覆盖区区域地质调查的核心是揭示晚新生代地表过程、圈层相互关系，探讨人与自然的关系，服务于国家生态文明建设与生态环境保护.然而，覆盖区进行地质填图一个很大的难处是第四纪松散沉积层的侧向延伸往往很不稳定，要特别重视重要构造-沉积-古气候和古环境事件，如重要的不整合面、侵蚀面、火山岩层、湖相沉积，重要的海侵层、古气候沉积(如黄土、红土、黑土)，古文化层等.它们可以作为第四纪松散沉积层侧向对比的重要标志，并且往往具有等时性.东亚大陆构造演化及现代地貌特征主要受两大地球动力系统所控制，西部印度-欧亚板块碰撞、高原快速隆升并向北东方向扩展，东部太平洋板块向欧亚大陆俯冲消减并在东亚大陆东缘形成复杂的沟-弧-盆系统.两大构造系统作用奠定了晚新生代以来中国地质演化背景，导致地球深部过程和地表环境发生重大变革.总体表现为青藏高原隆升、东部岩石圈伸展减薄，最终塑造了现今的宏观地貌形态和水系格局.本文针对第四纪松散沉积物覆盖层的这些特点，对中国晚新生代以来重要构造-沉积-古气候事件进行了梳理，总结了晚新生代这些重要事件的地质记录，特别是重要的沉积层、侵蚀面、不整合面、海侵层等，以便在覆盖区区域地质调查时对第四纪松散沉积层进行区域性对比.     

广西凭祥盆地深水底流沉积类型及其研究意义

内波、内潮汐沉积和复合流沉积是二十余年来在古代深水环境中新发现的一种具牵引流性质的沉积相类型,由于地层沉积记录十分有限,制约了深水底流沉积的沉积学研究。大比例尺实测地质剖面和精细露头测量表明,底流沉积发育于凭祥盆地深水沉积之中,通过对其沉积构造精细剖析和古水流测量,识别出内波、内潮汐沉积和复合流沉积,其中内波、内潮汐沉积以双向交错层理、单向交错层理、透镜状层理为特征,复合流沉积以复合流层理、丘状交错层理和较陡的爬升波纹层理为特征,进一步表明存在浊流和底流的交互作用,为古代地层中的深水底流沉积提供了又一研究实例。     

Lithostratigraphy and geochemistry of Upper Vendian‒Lower Cambrian deposits in the northeastern Baltic monocline

The results of investigations of Upper Vendian?Lower Cambrian deposits in the northeastern part of the Baltic monocline specify views on the evolution of depositional environments of sedimentary successions constituting the basal part of the sedimentary cover in inner areas of the northwestern East European Platform. It is shown that the Late Vendian and initial Cambrian were characterized by the consecutive influx of relatively mature terrigenous detrital material that originated from both the weathering crust of the Baltic Shield and new sources. Its deposition was interrupted by notable, although likely asynchronous, hiatuses, which are registered at the base of the Upper Vendian Vasileostrovskaya and Voronkovo formations and Lower Cambrian Lomonosov Formation. In the Late Vendian, sedimentary material was transported from the Baltic Shield, while beginning from the initial Early Cambrian the additional contribution to the formation of the sedimentary cover of the Baltic monocline was provided by coarse-grained sedimentary material from the Timan margin of the Baltica as follows from U?Pb isotopic ages obtained for detrital zircons. At the same time, lithogeochemical parameters of fine-grained rocks experienced no substantial changes.     

Late Pleistocene and early Holocene drainage events in the eastern Fehmarn Belt and Mecklenburg Bight,SW Baltic Sea

The Fehmarn Belt is a key area for the Late Pleistocene and Holocene development of the Baltic Sea as it was a passage for marine and fresh water during its different stages. The pre‐Holocene geological development of this area is presented based on the analysis of seismic profiles and sedimentary gravity cores. Late Pleistocene varve sediments of the initial Baltic Ice Lake were identified. An exceptionally thick varve layer, overlain by a section of thinner varves with convolute bedding in turn covered by undisturbed varves with decreasing thicknesses is found in the Fehmarn Belt. This succession, along with a change in varve geochemistry, represents a rapid ice‐sheet withdrawal and increasingly distal sedimentation in front of the ice margin. Two erosional unconformities are observed in the eastern Mecklenburg Bight, one marking the top of the initial Baltic Ice Lake deposits and the second one indicating the end of the final Baltic Ice Lake. These unconformities join in Fehmarn Belt, where deposits of the final Baltic Ice Lake are missing due to an erosional hiatus related to a lake‐level drop during its final drainage. After this lake‐level drop, a lowstand environment represented by river deposits developed. These deposits are covered by lake marls of Yoldia age. Tilting of the early glacial lake sediments indicates a period of vertical movements prior to the onset of the Holocene. Deposits of the earliest stages of the Baltic Sea have been exposed by ongoing erosion in the Fehmarn Belt at the transition to the Mecklenburg Bight.     

白龙江流域中上游第四纪沉积物的发育特征及其灾害效应

白龙江流域是我国四大地质灾害高发区之一,也是全国17个地质灾害重点防治区之一。第四纪沉积物的广泛分布为地质灾害提供了丰富的物质基础。本文基于遥感和GIS技术,结合影像特征和野外实际调查,建立了研究区第四纪成因类型（5大类11亚类）的解译标志;运用所建立的解译标志,对研究区进行了精细解译,新增第四纪残积物、坡积物、泥石流堆积和人工堆积等8个沉积亚类,补充和完善了滑坡堆积体和崩积物的面域数据,共解译第四纪沉积物面积444.7 km2,较前人研究资料扩展了380.4 km2;研究区上游段主要受地形地貌因素影响,第四纪沉积物沿白龙江主河道及其支流分布,中游段主要受地质构造控制,第四纪沉积物沿活动断层呈条带状分布,下游段主要受地层岩性影响,第四纪沉积物呈片状分布;第四纪沉积物灾害效应主要表现为崩滑效应和对泥石流的补给效应。本文研究成果对研究区区域地质灾害调查和风险评价提供了技术支撑。     

现代珠江三角洲地区QZK4孔第四纪沉积年代

在地质环境变迁迅速的现代珠江三角洲地区,对于第四纪沉积的年代存在多种认识。结合南中国海的海平面变化记录,通过AMS14C和光释光测年发现,珠江三角洲腹地QZK4孔第四纪岩心底部最老年龄约为43.71ka BP。岩心记录的第四纪环境对南中国海海平面变化有着良好的响应:岩心下部陆相河流沉积和暴露风化层发育于末次冰期至早全新世的低海平面时期,上部滨海—河口湾沉积发育于早中全新世以来的高海平面时期。根据钻孔岩心的环境分析,推测现代珠江三角洲地区第四纪的底界可能较本钻孔记录的更老。     

Late Weichselian and Holocene seismostratigraphy and depositional history of the Gulf of Riga,NE Baltic Sea

The Lateglacial and postglacial sequence in the northern Gulf of Riga is sedimentologically subdivided into nine distinctive layers. In the seismo‐acoustic sequence these layers are correlated with seven seismic/acoustic units, which largely reflect different stages in the development of the Baltic Sea. A uniform layer of the Late Weichselian till, a layer of waterlain glacial diamicton (WGD), a varved succession of the Baltic Ice Lake, a brackish‐water/freshwater sandy/silty clay of Yoldia Sea, a FeS‐rich layer of Ancylus Lake and discordantly bedded sand of the Litorina Sea and present‐day gyttja are revealed both in sediment cores and in acoustic recordings. In general, the lateral extent of the distinguished sediment layers is gradually shrinking upwards in the Quaternary sequence towards the deepest, central depression of the gulf. Two distinguished regional discontinuities divide the Lateglacial and postglacial sediment sequence into three allounits: glacial diamicton deposits in the lower part; ice‐proximal WGD, glaciolacustrine and postglacial lake/marine deposits in the middle; and brackish‐water marine deposits in the uppermost part of the sequence. The presented detailed seismostratigraphic subdivision of the Quaternary sediment sequence of the Gulf of Riga permits a correlation/comparison with similar sequences across the Baltic Sea and in other former glaciated basins.     

南海西北部中建南海底峡谷群的发现及演化特征

在南海西北部首次发现中建南峡谷群,目前对其地质信息尚未开展相关研究.综合利用水深地形数据和二维多道地震资料,主要分析中建南峡谷群的地形地貌特征、平面展布与分段性特点,精细刻画峡谷沉积充填结构及演化特征,再进一步讨论峡谷形成的控制因素.中建南海底峡谷群分布于中建阶地与中建北海台之间,它是由西侧的一条主轴峡谷和东侧的多条小型分支峡谷组成,整体呈SE-S-SE走向,以走向转折拐点为起点,将峡谷分为三段式:北段、中段和南段,北段以侵蚀作用为主,中段和南段主要受侵蚀作用、沉积作用,东南部的峡谷口外主要受沉积作用.研究区晚中新世?第四纪时广泛分布峡谷沉积体系,包括半深海相、三角洲相、峡谷/水道充填相、滑塌相、块体搬运复合沉积和浊积扇相.揭示了该海底峡谷群的发育和演化主要受海平面变化、沉积物源供给和重力流、底流作用的控制.通过对该峡谷群的地形地貌和沉积演化特征的分析,将对海洋地质灾害、南海深水沉积体系研究及油气资源勘探有重要的科学意义.      

Lithofacial complexes of quaternary deposits in the central and southeastern baltic sea

Geological and seismic profiling data (more than 25000 km of seismic profiles and about 1000 sediment sampling stations) collected during the last 30 yr by research vessels of the Shirshov Institute of Oceanology, Russian Academy of Sciences are summarized. Seismic records are directly correlated with sediment cores. The distribution map (scale 1 : 500000) of Quaternary lithofacial complexes corresponding to certain stages of the Baltic Sea evolution is compiled. The following four complexes are distinguished (from the base to the top): (I) moraine, with maximum thicknesses 60 and 170 m in valleys and ridges respectively: (II) varved clay of periglacial basins and from the Baltic Ice Lake (BIL), up to 25 m thick in depressions; (III) lacustrinemarine homogeneous clay with a thickness up to 4–8 m in depressions; (IV) marine sediments (mud, aleurite, coarse-grained deposits) accumulated in environments with intense bottom currents activity (thickness 2–4 m in the Gotland Basin, 4–6 m in the Gdansk Basin, and 10–20 m in fans and prodeltas). The Quaternary sequence is cut through by inherited valleys, where the thickest Holocene sediments are noted. Today, these valleys serve as routes of sediment transport to slope bases and central parts of basins. Outblows of deep gas (through faults and fractures) and diagenetic gas (from sediments) to the bottom surface also occur in the valleys. Sedimentation rates are higher in the Gdansk Basin (up to 100–120 cm/ka). Thick sand, aleurite, and mud bodies are accumulated here (about 15–20 m in the Visla River prodelta). The sedimentation rate is slower in the Gotland Basin (up to 50–60 cm/ka), where thin (2–4 m) sections of more fine-grained mud occur     

Structure of the Maikop complex of the Caspian Sea region based on seismic stratigraphic research

The paper reports on the structure of the Oligocene–Lower Miocene Maikop complex of the Caspian Sea and its margin on the basis of seismic and geological data. It is shown that the regional structure of Maikop deposits of Ciscaucasia and the Middle Caspian is characterized by large clinoform sedimentary bodies. New data on formation, structure, and occurrence of clinoforms in Maikop deposits are generalized for the researched region. Two main systems of clinoforms were defined in the Maikop complex: the single large cone located in the Middle Caspian and Eastern Ciscaucasia and the southeastern system of clinoforms located in the area of Kazakh Bay. Structural characteristics and sedimentogenesis of a clinoform formation are revealed using seismic and sequence stratigraphic methods.     

东海冲绳海槽天然气水合物成矿地质条件与资源潜力

冲绳海槽位于东海的东部,区内天然气水合物调查研究程度低。本文分析了冲绳海槽的区域地质背景和天然气水合物调查研究现状,根据已有资料和前人研究成果,分析了研究区天然气水合物形成的地形地貌、水深、温度、热流值特征,地层、沉积、构造、气源等条件,以及区内存在天然气水合物的地球物理、地球化学和其他证据,在此基础上推测区内天然气水合物成藏存在4种可能的地质类型。即成岩型、断裂构造型、底劈构造型和滑塌型。研究认为,冲绳海槽天然气水合物资源潜力巨大。     

Late Holocene Baltic Sea outflow changes reconstructed using C37:4 content from marine cores

The Baltic Sea is an intra‐continental brackish water body. Low saline surface water, the so‐called Baltic outflow current, exits the Baltic Sea through the Kattegat into the Skagerrak. Ingressions of saline oxygen‐rich bottom water enter the Baltic Sea basins via the narrow and shallow Kattegat and are of great importance for the ecological and ventilation state of the Baltic Sea. Over recent decades, progress has been made in studying Holocene changes in saline water inflow. However, reconstructions of past variations in Baltic Sea outflow changes are sparse and hampered because of the lack of suitable proxies. Here, we used the relative proportion of tetra‐unsaturated C₃₇ ketones (C_37:4 %) in long‐chain alkenones produced by coccolithophorids as a proxy for outflowing Baltic Sea water in the Skagerrak. To evaluate the applicability of the proxy, we compared the biomarker results with grain‐size records from the Kattegat and Mecklenburg Bay in addition to previously published salinity reconstructions from the Kattegat over the last 5000 years. All Skagerrak records showed an increase in C_37:4 % that is accompanied by enhanced bottom water currents in the Kattegat and western Baltic Sea over the past 3500 cal. a BP, indicating an increase in Baltic Sea outflow. This probably reflects higher precipitation in the Baltic Sea catchment area owing to a re‐organization of North Atlantic atmospheric circulation with an increased influence of wintertime Westerlies over the Baltic catchment from the mid‐ to the late Holocene.     

Structural and physiographic control on the Holocene marine sedimentation in the bay of Cadiz (SW Spain)

The Quaternary tectonic activity in the Gulf of Cadiz has considerably influenced the depositional regime and distribution of Holocene marine deposits. The aim of this work is to determine the nature of the recent sedimentary filling in the Bay of Cadiz sea bottom and adjacent continental shelf and to establish the main controlling factors on the Holocene marine sedimentation.

The sedimentary record indicates siliciclastic sedimentation supplied from the continent, with alternating episodes of high and low sedimentation rates. The recent sedimentary evolution of this marine area was controlled by the Late Quaternary eustatic fluctuations. Bathymetric, geophysical and drilling data have been employed to prepare a detailed isopach map of the non-consolidated recent sedimentary cover. Thickness distribution shows significant variations related to the infilling of former fluvial palaeochannels incised during the Late Pleistocene lowstand, and highly controlled by the structural neotectonic trends of faults and joints: NNW-SSE, NNE-SSW and ENE-WSW. The general distribution of isopachs in this area is clearly influenced by these morphostructural lines, which controlled the sedimentary processes during the Holocene. These results are coherent with the main regional neotectonic structures previously described in the nearby continental area, and confirm their prolongation towards the marine domain.     

Mid-Cretaceous Tuor-Yuryakh Section of Kotelnyi Island,New Siberian Islands: How Does the Probable Basement of Sedimentary Cover of the Laptev Sea Look on Land?

The model of geological structure of sedimentary cover of the Laptev Sea accepted by most geologists suggests that the lower seismic complex of the cover begins by the Aptian–Albian sedimentary rocks. They can be studied in natural outcrops of Kotelnyi Island. The section of the Tuor-Yuryakh Trough, which exposes the lower part of the Cretaceous complex, is described in the paper. It is composed of continental coaliferous rocks ~100 m thick. The marking beds divide it into five members, which are traced along the western wall of the trough at the distance up to 3 km. The spore–pollen complexes and plant megafossils indicate that almost the entire visible section of the mid-Cretaceous is Albian. Only its lower part no more than 14 m thick can probably belong to the Aptian. Marine facies with Albian foraminifers were found 15 m above the bottom of the Cretaceous complex. The section of the Cretaceous rocks is underlain by the Lower Jurassic marine clays and siltstones. The foraminifer assemblages of this part of the section are typical of the upper Sinemurian–Pliensbachian and fossil bivalves indicate late Sinemurian age of the host rocks. The hiatus ~70 Ma duration has no expression in the section and this boundary can de facto be substantiated only by microfossils. This vague contact between the Lower Jurassic and mid-Cretaceous rocks does not correspond to geophysical characteristics of the bottom of the lower seismic complex of the cover of the eastern part of the Laptev Sea. The latter is described as the most evident seismic horizon of the section of the cover, suggesting unconformable occurrence of the lower seismic complex on a peneplenized surface of lithified and dislocated rocks. This is mostly similar to the bottom of the Eocene sediments, which were observed on Belkovsky and Kotelnyi islands. The paper discusses possible application of our land results for interpretation of the shelf seismic sections of the Laptev Sea. It is concluded that local reasons are responsible for a vague boundary between the Lower Jurassic and mid-Cretaceous sequences in the section studied. Our observations support ideas on possible Aptian–Albian age of the rocks of the basement of the lower seismic complex; however, it is proposed to use also the previously popular idea on the Eocene age of the lower seismic complex of sedimentary cover of the eastern part of the Laptev Sea as one of the possible working scenarios.     

Groundwater Systems and Resources in the Ordos Basin, China

The Ordos Basin is a large-scale sedimentary basin in northwestern China.The hydrostratigraphic units from bottom to top are pre-Cambrian metamorphic rocks,Lower Paleozoic carbonate rocks,Upper Paleozoic to Mesozoic clastic rocks and Cenozoic deposits.The total thickness is up to 6000 m.Three groundwater systems are present in the Ordos Basin,based on the geological settings,i.e.the karst groundwater system,the Cretaceous clastic groundwater system and the Quaternary groundwater system.This paper describes systematically the groundwater flow patterns of each system and overall assessment of groundwater resources.     

The Late Quaternary Skagerrak and its depositional environment

The Skagerrak is a key region for our understanding of the Late Quaternary history of the East North Sea, of the entire Baltic basin and of the adjacent Scandinavian land areas. The depositional history of the postglacial Skagerrak began after the ice margin withdrew from Jutland to close to the modern Norwegian coast around 14 ka B.P. to 13 ka B.P. The Skagerrak was immediately filled by marine waters from the Norwegian Sea, but retained a fjord-like shape until approximately 10.2 ka B.P., when a connection opened across central Sweden to the Baltic Ice Lake. This seaway closed around 9 ka B.P., but a new seaway to the Baltic basin opened subsequently (probably close to 8.5 ka B.P.) through the Danish Belts. At about 10 ka B.P. the Skagerrak 'fjord' also started to change shape due to the flooding of the large former land area under the modern North Sea. Paleo-geography and -bathymetry of these changes can now be quantified in great detail. The young Quaternary sediments of the Skagerrak consist of fine-grained clays with minor amounts of silty and sandy material and are mostly of terrigenous origin, whereas biogenic components in general make up only a minor proportion of the bulk sediment. Prior to 10 ka B.P. a major portion of these deposits originated from the Fennoscandian regions N and E of the Skagerrak, while ice-rafting contributed coarse terrigenous components to the usually fine-grained sediments and while it was filled by brackish surface and cold polar bottom waters. At approximately 10 ka B.P., more temperate waters started to fill the Skagerrak and a good portion of the sediment seems to have originated from areas to the South. The Norwegian Coastal Current can only be documented for the past 7 ka; subtle changes of the pelagic and benthic environments could also be documented for later intervals.