共查询到20条相似文献,搜索用时 31 毫秒
1.
塔里木盆地苏盖特布拉克地区下寒武统肖尔布拉克组发育3种类型碳酸盐岩微生物(蓝细菌)建造,即下部微生物丘状和层状建造、中上部微生物礁和顶部叠层石建造。微生物丘状和层状建造的特点是似层状孔洞和纹层结构发育,形成于潮下高能带,与微生物席粘结有关,分布相对稳定。微生物礁是由枝状或丛状微生物骨架生长和微生物席粘结两种方式形成,分布较广,可分为两大期:第1大期发育在海退背景下,呈宏观块状建造特征;第2大期则发育在较大的海侵背景下,呈现两期点礁特征。叠层石建造发育在更大范围的海侵背景下,超覆于点状建造之上,要求的水动力条件相对较强,由微生物粘结作用形成,其中叠层石和核形石是其重要标志,仅分布在研究区北部的苏Ⅱ、苏Ⅲ和苏Ⅳ剖面近顶部。 相似文献
2.
华北地台大约从寒武纪第二世的晚期开始接受沉积,超覆在前寒武-寒武纪“巨型不整合面”之上,形成了一套二级海侵背景下的厚层陆表海硅质碎屑岩-碳酸盐岩混积序列,这套特别的地层序列在苗岭统和芙蓉统中包含了多种多样的微生物岩。研究区苗岭统出露较为完整,包括毛庄组、徐庄组、张夏组和崮山组,分别构成4个三级层序即SQ1至SQ4。在SQ2的高位体系域和强迫型海退体系域中,以及SQ3的高位体系域中发育了较为特别的由微生物岩构成的生物层、生物丘或生物丘复合体。微生物岩的种类和沉积环境包括形成于正常浪基面以下、潮下带低能环境的类型I迷宫状微生物岩,潮下带上部至潮间带中-高能环境的类型II和类型III迷宫状微生物岩,风暴浪基面之上浅水环境中的均一石,潮间带短柱状叠层石和潮上带近水平缓波状叠层石,以及高能鲕粒滩中的小型叠层石生物丘。通常认为寒武系苗岭统的微生物岩(礁)以凝块石和树形石为特征,而本次研究在苗岭统中发现了迷宫状微生物岩和均一石,补充丰富了对寒武系微生物岩(礁)多样化和复杂化构成的认识。无论是在迷宫状微生物岩、均一石中,还是叠层石中,都见到了一种或多种钙化蓝细菌(鞘)化石,如葛万菌(Girvanella)、附枝菌(Epithyton)和基座菌(Hedstroemia)等,以及大量的钙化微生物席残余物,表明这些微生物岩是由蓝细菌所主导的微生物席的复杂的钙化作用产物,而大量呈弥散状分布的黄铁矿晶体或颗粒则表明硫酸盐还原菌等非光合作用细菌和异养细菌可能在促进碳酸盐沉淀过程中扮演了重要角色。 相似文献
3.
基于岩心、薄片和测录井资料分析发现,鄂尔多斯盆地奥陶系马家沟组马五5亚段下部发育1套盆地尺度稳定分布的微生物碳酸盐岩组合,其特征为: (1)岩石类型主要由泥质灰(云)岩、泥晶灰(云)岩、凝块灰(云)岩、叠层灰(云)岩、粘结砂屑灰(云)岩及岩溶角砾灰(云)岩等构成,凝块石主要呈层状、瘤状和格架状,叠层石可识别出层纹状、波状和柱状3种类型;(2)垂向上可识别出4种与微生物岩密切相关的、向上变深复变浅的典型沉积序列;(3)高频旋回小层划分与对比分析发现,微生物岩在横向上稳定连片分布,具有盆地尺度的可对比性和等时性;(4)基于岩心刻度测井方法建立测井相模板,依据该模板对全盆地404口井进行逐一识别和解释,发现微生物碳酸盐岩的累计厚度一般在3~7m之间,整体呈向东减薄的变化趋势,连续分布面积超过2.5×105km2,揭示了较短时间内盆地尺度微生物岩规模发育的独特沉积现象。沉积序列分析表明,马五5亚段沉积初期存在单旋回缓慢变深复变浅、多旋回组合振荡式持续缓慢海侵的海平面变化趋势,且相对平静的古构造环境与早期蒸发岩填平补齐作用的耦合提供了相对平坦的古地貌条件,因此在马五5亚段沉积时期总体持续缓慢海侵背景下,环境同质化的底形条件是规模性浅水微生物碳酸盐岩发育的根本原因。系统报道马五5亚段盆地尺度微生物岩的发育与分布特征,既丰富了鄂尔多斯盆地奥陶系马家沟组微生物岩的研究,也有助于丰富完善对碳酸盐岩台地微生物岩规模性繁育机制的认识。 相似文献
4.
The Neoarchean Carawine Formation, Hamersley Group, Western Australia is a carbonate ramp that preserves diverse microbial structures which are characteristic of specific depositional environments. These distinctive structures are distributed in five shallow subtidal and two deeper‐water facies in the Oakover area of the Carawine Formation. The shallow subtidal facies are composed of biohermal and bedded stromatolites, centimetre‐scale ridge‐shaped microbialites and wavy‐laminated microbialites. The deeper‐water facies are composed of fenestrate microbialites, planar laminated dolostone and dolostone with rolled‐up microbial laminae. Microbialites in the Carawine Formation lie within a continuum of Archean to Proterozoic microbial facies. Some shallow‐water microbial facies in the Carawine Formation are similar to Proterozoic facies, such as large bioherms internally composed of a variety of stromatolite morphologies. In contrast, fenestrate microbialites grew in quiet subtidal environments and are common in Archean rocks but have not been documented in similar Proterozoic environments. The similarity of shallow‐water facies across the Archean–Proterozoic transition, before and after the oxidation of the atmosphere and surface oceans, indicates that stromatolite growth in shallow subtidal environments was not strongly affected by the chemical changes associated with oxidation of the oceans or by biological responses to those chemical changes. Rather, stromatolite morphology was controlled mostly by the physical environment and the corresponding biological responses to that environment. In contrast, the absence of fenestrate microbialites from Proterozoic deep subtidal environments suggests that the morphology of deep subtidal microbial structures was influenced by chemical or biological changes that occurred in association with oxidation of the surface oceans. 相似文献
5.
The preservation potential of some recent stromatolites 总被引:3,自引:0,他引:3
ROBERT K. PARK 《Sedimentology》1977,24(4):485-506
Stromatolites are laminated organo-sedimentary structures, generally compared to present day blue-green algal mats. Their morphology, species composition and overall extent are largely governed by the amount of wetting, although other factors such as competition, predation and desiccation, also contribute. The Trucial Coast mats are essentially intertidal. Stromatolite accretion rates in this area are of the order of 0·2 mm p.a. but lamina growth is far from regular. The area is also characterized by the development of evaporites, especially gypsum which proves to be an important agent of mat destruction. The growth of crystals causes disruption within the upper portions of the stromatolite section with the result that none of the upper intertidal mat forms are preserved. Other agencies of destruction include bacterial decay, desiccation and dehydration, and compaction under burial which may depress and deform the original mat relief. Decay results in the almost total loss of cellular contents, only a few empty sheaths and the pigment surviving into the fossil record. Preservation may be effected via (a) burial or (b) lithification. However, few modern algal mat structures bear any resemblance to fossil stromatolite heads with the exception of those from Shark Bay. From this, one might infer that pene-contemporaneous lithification is a prerequisite for their preservation. 相似文献
6.
PETER A. DRUSCHKE GANQING JIANG THOMAS B. ANDERSON† ANDREW D. HANSON 《Sedimentology》2009,56(5):1275-1291
Well-preserved siliciclastic domal stromatolites, up to 2 m wide and 1·5 m high, are found in a 10 to 15 m thick interval within the Late Ordovician Eureka Quartzite of Southern Nevada and Eastern California, USA. These stromatolites appear as either isolated features or patchy clusters that contain more than 70% by volume quartz grains; their association with planar, trough and herringbone cross-bedding suggests that they were formed in an upper shoreface environment with high hydraulic energy. In this environment, sand bars or dunes may have provided localized shelter for initial microbial mat colonization. Biostabilization and early lithification of microbial mats effectively prevented erosion during tidal flushing and storm surges, and the prevalence of translucent quartz sand grains permitted light penetration into the sediment, leading to thick microbial mat accretion and the formation of domal stromatolites. Decimetre-scale to metre-scale stromatolite domes may have served as localized shelter and nucleation sites for further microbial mat colonization, forming patchy stromatolite clusters. Enrichment of iron minerals, including pyrite and hematite, within dark internal laminae of the stromatolites indicates anaerobic mineralization of microbial mats. The occurrence of stromatolites in the Eureka Quartzite provides an example of microbial growth in highly stressed, siliciclastic sedimentary environments, in which microbial communities may have been able to create microenvironments promoting early cementation/lithification essential for the growth and preservation of siliciclastic stromatolites. 相似文献
7.
Microbial deposits in the aftermath of the end‐Permian mass extinction: A diverging case from the Mineral Mountains (Utah,USA) 
下载免费PDF全文
下载免费PDF全文 Emmanuelle Vennin Nicolas Olivier Arnaud Brayard Ivan Bour Christophe Thomazo Gilles Escarguel Emmanuel Fara Kevin G. Bylund James F. Jenks Daniel A. Stephen Richard Hofmann 《Sedimentology》2015,62(3):753-792
The Lower Triassic Mineral Mountains area (Utah, USA) preserves diversified Smithian and Spathian reefs and bioaccumulations that contain fenestral‐microbialites and various benthic and pelagic organisms. Ecological and environmental changes during the Early Triassic are commonly assumed to be associated with numerous perturbations (productivity changes, acidifica‐tion, redox changes, hypercapnia, eustatism and temperature changes) post‐dating the Permian–Triassic mass extinction. New data acquired in the Mineral Mountains sediments provide evidence to decipher the relationships between depositional environments and the growth and distribution of microbial structures. These data also help to understand better the controlling factors acting upon sedimentation and community turnovers through the Smithian–early Spathian. The studied section records a large‐scale depositional sequence during the Dienerian(?)–Spathian interval. During the transgression, depositional environments evolved from a coastal bay with continental deposits to intertidal fenestral–microbial limestones, shallow subtidal marine sponge–microbial reefs to deep subtidal mud‐dominated limestones. Storm‐induced deposits, microbialite–sponge reefs and shallow subtidal deposits indicate the regression. Three microbialite associations occur in ascending order: (i) a red beds microbialite association deposited in low‐energy hypersaline supratidal conditions where microbialites consist of microbial mats and poorly preserved microbially induced sedimentary structure; (ii) a Smithian microbialite association formed in moderate to high‐energy, tidal conditions where microbialites include stromatolites and associated carbonate grains (oncoids, ooids and peloids); and (iii) a Spathian microbialite association developed in low‐energy offshore conditions that is preserved as multiple decimetre thick isolated domes and coalescent domes. Data indicate that the morphologies of the three microbialite associations are controlled primarily by accommodation, hydrodynamics, bathymetry and grain supply. This study suggests that microbial constructions are controlled by changes between trapping and binding versus precipitation processes in variable hydrodynamic conditions. Due to the presence of numerous metazoans associated with microbialites throughout the Smithian increase in accommodation and Spathian decrease in accommodation, the commonly assumed anachronistic character of the Early Triassic microbialites and the traditional view of prolonged deleterious conditions during the Early Triassic time interval is questioned. 相似文献
8.
We present the first study of micro‐crustaceans (ostracods) associated with microbial crusts in the aftermath of the most devastating extinction, the end‐Permian extinction (EPE). These post‐extinction microbialites dominated shallow shelf marine environments and were traditionally considered as devoid of any associated fauna. We present a micro‐palaeontological analysis of a large record from microbial and non‐microbial settings following the EPE. This dataset documents the proliferation of ostracods strictly associated with microbialites. Based on the diet of extant ostracods and uniformitarianism, we propose that the abundant microbes in the mats served as an unlimited food supply. Photosynthetic cyanobacteria may also have locally provided oxygen under low oxygen conditions interpreted by others for the microbialites. Microbialites provided a specialised environment that may have acted as refuge for ostracods in the immediate aftermath of the EPE. The surviving faunas may have been progenitors for the starting of the latter radiation. 相似文献
9.
Ancient microbialites reflect interactions between microbial communities and environmental conditions. However, evaluating the relative roles of microbial community processes and environmental influences on microbialite morphology and internal fabric in the rock record can be challenging. The Neoproterozoic Beck Spring Dolomite preserves diverse microbialites, and thus provides an opportunity to explore the factors that influenced microbialite development locally. Stromatolitic, thrombolitic and composite microbialites are abundant in subtidal to upper intertidal carbonates in the Beck Spring Dolomite. Thrombolitic and composite microbialites have not been recognized previously in this unit, but compose much of the newly defined thrombolitic member. Stratigraphic relationships demonstrate that these three types of microbialites formed in close spatial and temporal association in subtidal to intertidal environments. The relative proportions and distributions of stromatolitic and thrombolitic microbialites vary with depositional environment; stromatolitic microbialites dominate in deeper intertidal to subtidal facies, whereas thrombolitic textures are more abundant in upper intertidal facies. Composite microbialites, composed of intermingled clotted and laminated textures, formed in all environments but are most abundant in intertidal facies. The broad environmental distribution of stromatolitic, thrombolitic and composite microbialites and the intermingling of textures suggest that laminated and clotted textures reflect diverse microbial community morphologies rather than environmental variations. Furthermore, the ca 750 Ma age of thrombolitic microbialites in the Beck Spring Dolomite requires that they formed without the influence of calcimicrobes or metazoans colonizing and grazing the microbial mat surface. Thus, these thrombolites provide further evidence that the biostratigraphic distribution of thrombolites cannot be uniquely attributed to evolution of calcifying and grazing organisms in the earliest Cambrian, and that older microbial communities were capable of producing clotted textures. 相似文献
10.
Studies of modern cyanobacterial mats and biofilms show that they can precipitate minerals as a consequence of metabolic and degradational activities paired with ambient hydrochemical conditions. This study looked at modern microbial mats forming giant, tower‐like, groundwater‐fed, calcareous microbialites in the world's largest, highly alkaline lake; Van Gölü (Lake Van), East Turkey. Results show that microbial systems play a role not only in carbonate precipitation but also in the formation of siliceous mineral phases. Transmitted light microscopy, scanning electron microscopy and spectral observations revealed that, within the extracellular polymeric substances excreted by the mats abundant minute aragonite grains precipitated first in vivo. These minute grains were quickly succeeded and/or supplemented in the dead biomass of the cyanobacterial mat by authigenic Al–Mg–Fe siliceous phases. Silicon dioxide is available in large concentrations in the highly alkaline water of Lake Van. Divalent cations (Ca and Mg) are delivered to the microbialites mostly by groundwater springs. The precipitation of the fine‐grained siliceous phases is probably mediated by bacteria degrading the cyanobacterial biomass and complexing the excessive cations with their extracellular polymeric envelopes. The bacteria serve as nucleation centres for the subsequent precipitation of siliceous mineral phases. Generally, the biphasic (calcareous and siliceous) mineralization – characterizing Lake Van microbialites – is controlled by their interior highly dynamic hydrogeochemical situation. There, the dramatically different alkaline lake water and the Ca–Mg‐charged groundwater mix at various rates. The early diagenetic replacement of the in vivo aragonite by authigenic siliceous phases significantly increases the fossilization potential of the mat‐forming cyanobacteria. Lake Van and its giant microbialite tufa towers act as a model explaining the transformation of early diagenetic mineral phases observed in many modern and ancient carbonate marine deposits, particularly those influenced by diffusion of silica‐enriched and metal‐enriched pore waters from below the water–sediment interface. 相似文献
11.
基于岩芯、薄片及物性资料,研究鄂尔多斯盆地东北部奥陶系马五1+2微生物岩沉积特征及其油气储集意义。研究区发育有不同规模的由蓝细菌群落构成的微生物碳酸盐岩建造,由叠层石、菌纹层白云岩、蓝细菌凝块岩以及菌黏结颗粒岩构成了藻坪和微生物丘建造。微生物丘纵向上建造规模较小,单旋回厚度一般小于1 m,发育于潮下高能环境,并由花斑状砂屑云岩、蓝细菌凝块岩、菌黏结砂屑云岩、菌纹层白云岩构成了丘基-丘核-丘坪的向上变浅序列,也常与颗粒滩相伴生构成丘滩复合体。其中,发育于丘核部位的蓝细菌凝块岩和菌黏结砂屑云岩中窗格孔和粒间孔发育,表现为中孔低渗特征,可作为盆地东北部的储集岩之一。 相似文献
12.
Giovanni Aloisi 《Geochimica et cosmochimica acta》2008,72(24):6037-6060
Through early lithification, cyanobacterial mats produced vast amounts of CaCO3 on Precambrian carbonate platforms (before 540 Myr ago). The superposition of lithified cyanobacterial mats forms internally laminated, macroscopic structures known as stromatolites. Similar structures can be important constituents of Phanerozoic carbonate platforms (540 Myr to present). Early lithification in modern marine cyanobacterial mats is thought to be driven by a metabolically-induced increase of the CaCO3 saturation state (ΩCaCO3) in the mat. However, it is uncertain which microbial processes produce the ΩCaCO3 increase and to which extent similar ΩCaCO3 shifts were possible in Precambrian oceans whose chemistry differed from that of the modern ocean. I developed a numerical model that calculates ΩCaCO3 in cyanobacterial mats and used it to tackle these questions. The model is first applied to simulate ΩCaCO3 in modern calcifying cyanobacterial mats forming at Highborne Cay (Bahamas); it shows that while cyanobacterial photosynthesis increases ΩCaCO3 considerably, sulphate reduction has a small and opposite effect on mat ΩCaCO3 because it is coupled to H2S oxidation with O2 which produces acidity. Numerical experiments show that the magnitude of the ΩCaCO3 increase is proportional to DIC in DIC-limited waters (DIC < 3-10 mM), is proportional to pH when ambient water DIC is not limiting and always proportional to the concentration of Ca2+ in ambient waters. With oceanic Ca2+ concentrations greater than a few millimolar, an appreciable increase in ΩCaCO3 occurs in mats under a wide range of environmental conditions, including those supposed to exist in the oceans of the past 2.8 Gyr. The likely lithological expression is the formation of the microsparitic stromatolite microtexture—indicative of CaCO3 precipitation within the mats under the control of microbial activity—which is found in carbonate rocks spanning from the Precambrian to recent. The model highlights the potential for an increase in the magnitude of the ΩCaCO3 shift in cyanobacterial mats throughout Earth’s history produced by a decrease in salinity and temperature of the ocean, a decrease in atmospheric pCO2 and an increase in solar irradiance. Such a trend would explain how the formation of the microsparitic stromatolite microtexture was possible as the ΩCaCO3 of the ocean decreased from the Paleoproterozoic to the Phanerozoic. 相似文献
13.
Fine‐grained agglutinated elongate columnar stromatolites: Tieling Formation,ca 1420 Ma,North China 下载免费PDF全文
下载免费PDF全文 The Mesoproterozoic Tieling Formation, near Jixian, northern China, contains thick beds of vertically branched, laterally elongate, columnar stromatolites. Carbonate mud is the primary component of both the stromatolites and their intervening matrix. Mud abundance is attributed to water column ‘whiting’ precipitation stimulated by cyanobacterial photosynthesis. Neomorphic microspar gives the stromatolites a ‘streaky’ microfabric and small mud flakes are common in the matrix. The columns consist of low‐relief, mainly non‐enveloping, laminae that show erosive truncation and well‐defined repetitive lamination. In plan view, the columns form disjunct elongate ridges <10 cm wide separated by narrow matrix‐filled runnels. The stromatolite surfaces were initially cohesive, rather than rigid, and prone to scour, and are interpreted as current aligned microbial mats that trapped carbonate mud. The pervasive ridge–runnel system suggests scale‐dependent biophysical feedback between: (i) carbonate mud supply; (ii) current duration, strength and direction; and (iii) growth and trapping by prolific mat growth. Together, these factors determined the size, morphology and arrangement of the stromatolite columns and their laminae, as well as their branching patterns, alignment and ridge–runnel spacing. Ridge–runnel surfaces resemble ripple mark patterns, but whether currents were parallel and/or normal to stromatolite alignment remains unclear. The formation and preservation of Tieling columns required plentiful supply of carbonate mud, mat‐building microbes well‐adapted to cope with this abundant sediment, and absence of both significant early lithification and bioturbation. These factors were time limited, and Tieling stromatolites closely resemble coeval examples in the Belt‐Purcell Supergroup of Laurentia. The dynamic interactions between mat growth, currents and sediment supply that determined the shape of Tieling columns contributed to the morphotypical diversity that characterizes mid–late Proterozoic branched stromatolites. 相似文献
14.
山东肥城邓家庄剖面寒武系出露连续,构成了7个三级层序。微生物碳酸盐岩主要发育在高位体系域和强迫型海退体系域单元中,以徐庄组凝块石、张夏组核形石、长山组叠层石、凤山组均一石为代表,是研究早古生代微生物碳酸盐岩复苏期的良好实例。多样化的微生物碳酸盐岩中可见大量保存精美的附枝菌(Epiphyton)、葛万菌(Girvanella)以及肾形菌(Renalcis)等钙化微生物残余物,指示了微生物碳酸盐岩形成与蓝细菌为主导的微生物新陈代谢活动密切相关。此外,微生物碳酸盐岩沉积特征反映了生长环境的分异性:均一石、凝块石分别生长在潮下带下部、上部;柱状叠层石主要发育在能量较高的潮间带环境;核形石指示了沉积环境浅且能量高的鲕粒滩相沉积环境。邓家庄寒武系剖面微生物碳酸盐岩为了解寒武纪地球微生物、古环境、古气候提供了重要的岩石记录。 相似文献
15.
河北承德路通沟剖面芙蓉统凤山组中部发育厚层块状叠层石生物丘,构成一个淹没不整合型层序的强迫型海退体系域,指示这些叠层石形成于中高能浅海环境。该生物丘宏观上主要由柱状叠层石组成,叠层石内部纹层较粗糙,在构成叠层石的致密泥晶和微亮晶组构中,还见到球粒、底栖鲕粒及凝聚颗粒等多种生物成因颗粒类型,代表着复杂的微生物活动特征,以此而区别于前寒武纪的叠层石。更为重要的是,叠层石生物丘中的致密泥晶基质中发育一些“石松藻(Lithocodium)”状的钙化蓝细菌菌落残余物,以及一些丝状钙化蓝细菌化石,指示了形成叠层石的微生物席为蓝细菌所主导的微生物席。因此,凤山组叠层石生物丘内复杂而特殊的碳酸盐岩沉积组构为研究叠层石形成过程中复杂的微生物代谢活动所产生的钙化作用机制提供了一个宝贵的地质实例。 相似文献
16.
Microbial mats, mainly dominated by filamentous algae Calothrix and Oscillatoria, are well developed in Tibetan hot springs. A great number of fossil microorganisms, which existed as algae lamination in thermal depositional cesium-bearing geyserite in this area, are identified as Calothrix and Oscillatoria through microexamination and culture experiments. These microbial mats show the ability to accumulate cesium from spring water to the extent of cesium concentration of 0.46–1.03% cell dry weight, 900 times higher than that in water, and capture large numbers of cesium-bearing opal grain. Silicon dioxide colloid in spring water replaces and fills with the organism and deposits on it to form algae laminated geyserite after dehydration and congelation. Cesium in the microbial mats and opal grain is then reserved in the geyserite. Eventually, cesium-bearing algae laminated geyserite is formed. Study on cesium distribution in geyserite also shows that cesium content in algae lamination, especially in heavily compacted algae lamination, is higher than in the opal layer. For geyserite with no algae lamination or other organism structure, which is generally formed in spring water with low silicon content, cesium accumulation and cesium-bearing opal grain assembled by the microbial mats are also indispensable. After the microbial mats accumulating cesium from spring water, silicon dioxide colloid poorly replaces and fills with the organism to form opal grain-bearing tremellose microbial mats. The shape and structure of the organisms are then destroyed, resulting in cesium-bearing geyserite with no algae lamination structure after dehydration and congelation. It is then concluded that microbial mats in the spring area contribute to the enrichment of cesium in the formation of cesium-bearing geyserite, and a biological genesis of the geyserite, besides of the physical and chemical genesis, is likely. 相似文献
17.
Development of microbial carbonates in the Lower Cretaceous Codó Formation (north‐east Brazil): Implications for interpretation of microbialite facies associations and palaeoenvironmental conditions 下载免费PDF全文
下载免费PDF全文 Anelize M. Bahniuk Sylvia Anjos Almério B. França Nilo Matsuda John Eiler Judith A. Mckenzie Crisogono Vasconcelos 《Sedimentology》2015,62(1):155-181
The study of microbial carbonates has acquired new significance with the recognition that they retain valuable information related to biomineralization processes associated with microbial activity throughout geological time. Additionally, microbialites have a demonstrated economic potential to serve as excellent hydrocarbon reservoirs. The Lower Cretaceous Codó Formation, located in the Parnaiba Basin of north‐east Brazil, comprises a unique stratigraphic sequence of up to 20 m thick, well‐preserved carbonate microbialites. Deposited in a continental basin during the initial break up and separation of South America from Africa in the Early Cretaceous, this lacustrine carbonate sequence provides an excellent example to investigate the palaeoenvironmental conditions controlling microbialite facies development. Based on macroscopic and microscopic observations of outcrop and drill core samples, four microbialite facies (stromatolite, lamina, massive and spherulite) were defined and distinguished by textures and microbial fossil content. Changes in facies type are related to alternating palaeo‐water depths, as reflected by 87Sr/86Sr cycles resulting from fluctuations in the sources of meteoric water. Clumped isotope measurements of stromatolitic fabrics yield precipitation palaeo‐temperatures with an average value of 35°C. The δ18O values of bulk carbonate (?6·8 to ?1·5‰ Vienna Pee Dee Belemnite) imply precipitation from water with calculated δ18O values between ?1·6‰ and 1·8‰ Vienna Standard Mean Ocean Water, reflecting precipitation from variably modified meteoric waters. The δ13C values of bulk carbonate (?15·5 to ?7·2‰ Vienna Pee Dee Belemnite) indicate a significant input of carbon derived from aerobic or anaerobic respiration of organic matter. Combined, the data indicate that the evolution of the Codó Formation occurred in a closed lacustrine palaeoenvironment with alternating episodes of contracting and expanding lake levels, which led to the development of specific microbialite facies associations. The results provide new insights into palaeoenvironmental settings, biogenicity and early diagenetic processes involved in the formation of ancient carbonate microbialites and, by extension, improve the knowledge of the reservoir geology of correlative units in deep waters offshore Brazil. 相似文献
18.
寒武纪初期不仅发生了宏体生物大爆发,而且也出现了地质历史时期少见的蓝细菌鞘体大规模钙化事件。埃迪卡拉纪—寒武纪之交海水化学性质的转变对真核生物的演化起到了重要作用,但是这种转变对微生物岩发育特征以及蓝细菌钙化事件的产生有无影响,目前尚不明确。鉴于此,对华南上扬子北缘汉南—米仓山地区上埃迪卡拉统—寒武系第二统多个典型微生物岩发育剖面进行了系统野外调查和室内岩石学分析,结果表明:上埃迪卡拉统灯影组叠层石广泛发育,以平铺状、缓波状特征为主,而凝块石既可以呈补丁状分布于叠层石纹层间,又可以呈细小的凝絮状、粘结状特征构成厚层岩层;寒武系第二统仙女洞组叠层石丰度显著降低,以高大、坚硬的丘状隆起为特点,包括单独的凝块石丘,以及微生物与古杯的联合建丘。虽然寒武系第二统微生物岩的层状结构和凝块结构与埃迪卡拉系相比并无太大差异,但是寒武系微生物岩内部保存有大量的钙化微生物化石,已识别出附枝菌(Epiphyton)、肾形菌(Renalcis)和葛万菌(Girvanella)等多种类型。在收集、整理前人有关微生物岩特征和发育资料的基础上,本次研究初步整理出华南寒武系第二统微生物岩的时空分布特点,发现寒武纪第二世第三期是钙化微生物大量发育的一个时期,在随后的第四期达到一个小的高峰。对于此次蓝细菌钙化作用幕的启动机制,除前人提出的海水高钙离子浓度和蓝细菌体内二氧化碳浓缩机制等认识外,寒武纪早期海水性质的转变(方解石质原生矿物受成岩改造程度较低)、适度的陆源碎屑输入(黏土组分保护作用)也有利于钙化微生物结构的保存,应引起重视。 相似文献
19.
Marie-Béatrice Forel 《Comptes Rendus Geoscience》2013,345(4):203-211
The end-Permian mass extinction (EPE), about 252 Myr ago, eradicated more than 90% of marine species. Following this event, microbial formations colonised the space left vacant after extinction of skeletonised metazoans. These post-extinction microbialites dominated shallow marine environments and were usually considered as devoid of associated fauna. Recently, several fossil groups were discovered together with these deposits and allow discussing the palaeoenvironmental conditions following the EPE. At the very base of the Triassic, abundant Ostracods (Crustacea) are systematically present, only in association with microbialites. Bacterial communities building the microbial mats should have served as an unlimited food supply. Photosynthetic cyanobacteria may also have locally provided oxygen to the supposedly anoxic environment: microbialites would have been refuges in the immediate aftermath of the EPE. Ostracods temporarily disappear together with microbialites during the Griesbachian. 相似文献
20.
Silicified carbonates of the late Mesoproterozoic to early Neoproterozoic Society Cliffs Formation, Baffin Island, contain distinctive microfabrics and microbenthic assemblages whose paleo-environmental distribution within the formation parallels the distribution of these elements through Proterozoic time. In the Society Cliffs Formation, restricted carbonates--including microdigitate stromatolites, laminated tufa, and tufted microbial mats--consist predominantly of synsedimentary cements; these facies and the cyanobacterial fossils they contain are common in Paleoproterozoic successions but rare in Neoproterozoic and younger rocks. Less restricted tidal-flat facies in the formation are composed of laminated microbialites dominated by micritic carbonate lithified early, yet demonstrably after compaction; these strata contain cyanobacteria that are characteristic in Neoproterozoic rocks. Within the formation, the facies-dependent distribution of microbial populations reflects both the style and timing of carbonate deposition because of the strong substrate specificity of benthic cyanobacteria. A reasonable conclusion is that secular changes in microbenthic assemblages through Proterozoic time reflect a decrease in the overall representation of rapidly lithified carbonate substrates in younger peritidal environments, as well as concomitant changes in the taphonomic window of silicification through which early life is observed. 相似文献