中元古界非叠层石灰岩中的MISS:以北京延庆千沟剖面高于庄组第三段为例

前寒武纪碳酸盐岩多以叠层石碳酸盐岩序列为特征。燕山地区中元古界高于庄组,其中的第三段(张家裕亚组)则为一个以灰岩为主、贫乏叠层石的碳酸盐岩沉积序列,该序列被定义为前寒武纪非叠层石碳酸盐岩序列。该非叠层石碳酸盐岩沉积序列,尤其以燕山西部的延庆千沟剖面最为典型。根据沉积相序列及其所反映的旋回性,可以将该剖面的高于庄组第三段划分为3个三级层序。在这些三级层序的海侵体系域和早期高水位体系域中,中薄层隐晶质泥晶灰岩(均一石灰岩)和灰黑色薄层泥灰岩组成若干潮下型米级旋回;而在隐晶质泥晶灰岩层面上,普遍发育各种奇形怪状的沉积构造。这些沉积构造包括穹窿状构造、规则网状和杂乱的帐篷脊、变余波痕等,构成一个潮下相灰岩层面上的特别的微生物形成的沉积构造(Microbial Induced Sedimentary Structure,MISS)组合。因此,延庆千沟剖面的高于庄组第三段,特别的岩石类型和沉积构造成为前寒武纪碳酸盐岩沉积中非叠层石碳酸盐岩沉积序列的典型代表,尤其是那些奇形怪状的MISS所代表的沉积学特点表明:在前寒武纪,即使在叠层石生长的黄金时段,也发育非叠层石碳酸盐岩沉积序列。因此,这些现象将特别有助于对前寒武纪非叠层石生态系所造成的另一类席底生境的深入理解,也有助于复杂多变的碳酸盐岩世界。     

Microbially induced sedimentary structures in Archean sandstones: A new window into early life

Until now, the most valuable information on the early life on the Archean Earth derived from bacterial fossils and stromatolites preserved in precipitated lithologies such as chert or carbonates. Also, shales contain complex biomarker molecules, and specific isotopes constitute an important evidence for biogeneicity.In contrast, because of their low potential of fossil preservation, sandstones have been less investigated. But recent studies revealed a variety of ‘microbially induced sedimentary structures — MISS’ that differ greatly from any other fossils or sedimentary structures. ‘Wrinkle structures’, ‘multidirected ripple marks’, ‘biolaminites’, and other macrostructures indicate the former presence of photoautotrophic microbial mats in shallow-marine to tidal paleoenvironments. The MISS form by the mechanical interaction of microbial mats with physical sediment dynamics that is the erosion and deposition by water agitation. The structures occur not only in Archean tidal flats, but in equivalent settings throughout Earth history until today.MISS are not identified alone by their macroscopic morphologies. In thin-sections, the structures display the carpet-like fabrics of intertwined filaments of the ancient mat-constructing microorganisms. Geochemical analyses of the filaments proof their composition of iron minerals associated with organic carbon.In conclusion, microbial mats colonize sandy tidal settings at least for 3.2 Ga years. Therefore, Archean sandstones constitute an important archive for the exploration of early life.     

四川会理—会东及邻区中元古界昆阳群沉积特征及演化

四川会理 会东及邻区中元古界昆阳群 ,由下而上可分为力马河组、凤山营组和天宝山组 ,与古元古界河口群为不整合接触 ,其代表年龄值为 1 70 0± 1 0 0Ma～ 1 2 0 0± 1 0 0Ma。对这套地层的沉积学研究 ,前人涉及甚少。笔者在野外考察和室内分析的基础上 ,对其沉积相和沉积环境进行了详细的研究。初步认为研究区的中元古界昆阳群可分为 7种沉积相 ,进而探讨了该区的沉积演化历史。     

Late Precambrian tidal-flat deposits and algal stromatolites in the Båtsfjord formation,East Finnmark,North Norway

The Annijokka Member of the Late Precambrian Båtsfjord Formation consists of about 300 m of siliciclastic and carbonate deposits which accumulated on tidal flats, and includes several horizons of stromatolite biostromes. Seven main lithofacies are arranged in fining-up cycles a few metres thick. The cycles are terrigenous in the lower part and carbonate-rich higher up and are interpreted as reflecting shallowing-up conditions of deposition. Lithofacies distribution in the member as a whole also shows an upward decrease in the terrigenous component and grain size and increase in carbonates, thus suggesting that the Annijokka Member is regressive.The stromatolite biostromes of the member contain domal forms composed of calcite while the non-stromatolitic, though possibly in part algal-laminated, carbonate-rich beds of the member are dolomitic. This contrasting mineralogy suggests (1) penecontemporaneous supratidal dolomitization, and (2) a possibly freshwater-influenced origin of the domal stromatolites.     

Stromatolites: a guideline for development of a carbonate ramp,Basantpur Formation,Neoproterozoic Simla Group in Lesser Himalaya,India

Outcrop-based facies analysis of the Proterozoic Basantpur Formation, Simla Group in the Lesser Himalaya was combined with the stromatolites morphometry and sea-level fluctuation to delineate the stages of carbonate ramp development. On this basis, a vertical profile depositional model (Basantpur type) has been developed. Facies associations and variation in the patterns of microbial growth along with the sea-level fluctuations have contributed to the identification of the development of a tide-influenced carbonate ramp. Different stromatolitic structures (mega-, macro- and microstructures) are documented in the dolomudstones and dolosiltstones along with fenestral structures and their depositional facies together with evidences of marine transgression which leads to development of carbonate ramp where inner-mid-outer-ramp subenvironments are recognised. The “Basantpur”-type model is therefore unique in that it deals with lateral facies variation due to shift in shore line along with fluctuations in accommodation space on a carbonate ramp owing to fluctuations of sea level. This model will probably find its applicability in similar carbonate ramps.     

A Paleoproterozoic drowned carbonate platform on the southeastern margin of the Wyoming Craton: a record of the Kenorland breakup

The Nash Fork Formation in the upper part of the early Paleoproterozoic Snowy Pass Supergroup, Medicine Bow Mountains of Wyoming, was deposited on a mature passive margin along the southern flank of the Wyoming Craton and straddles the end of the ca. 2.2–2.1 Ga carbon isotope excursion. Two drowning events marked by black shales subdivide the carbonate platform into three parts. The lower Nash Fork Formation consists of outer shelf to supratidal deposits represented by massive and stromatolitic dolomites, heterolithic siliciclastics-carbonates, large silicified domal digitate stromatolites, nodular dolomites and stromatolitic dolomites. Molds after evaporite crystals are pervasive in the heterolithic siliciclastics-carbonates. Large silicified domal digitate stromatolites formed biostromes and bioherms following flooding events. The middle Nash Fork Formation comprises two intervals of black shale separated by inner shelf heterolithic siliciclastics-nodular carbonates. Black shales are organic- and pyrite-rich, contain turbidites and developed in response to drowning of the platform. Overlying massive dolomite of the upper Nash Fork Formation was deposited in an unprotected intertidal setting and displays an upward-shallowing trend terminated by a prominent karstic surface in the middle of the unit. The Nash Fork Formation is open-marine with no evidence for restricted circulation on the carbonate platform. The two drowning events on the carbonate platform are likely related to dissection of the mature passive margin associated with the breakup of Kenorland. The younger drowning event is associated with the end of the carbon isotope excursion. The main building elements of the lower and middle Nash Fork carbonate platform are dolomitic mudstones and stromatolites. Macroscopic seafloor precipitates are volumetrically negligible with the exception of tufa deposits and domes in the massive and stromatolitic dolomites and, possibly, digitate stromatolites within domal digitate stromatolites. The upper Nash Fork Formation comprises dolomitic mudstones, relatively rare stromatolites and inorganic precipitates that are more common than in the underlying carbonates. Styles of carbonate deposition on this early Paleoproterozoic platform differ from those documented on late Archean carbonate platforms; there are fewer macroscopic seafloor precipitates and more dolomitic mudstones. This pattern is considered to be related to a rise of the atmospheric oxygen level that led to a decrease in bicarbonate saturation in the ocean.     

Tide-dominated offshore sedimentation, Lower Cambrian, north Norway

The Duolbasgaissa Formation, Lower Cambrian, of northern Norway consists of 550 m of mineralogically and texturally mature sandstones with subordinate siltstones, mudstones and conglomerates. Four facies are defined on the basis of grain size, bed thickness and sedimentary structures. Facies 1–3 consist of a variety of erosively-based, cross-stratified and parallel-stratified sandstones interbedded with siltstone and mudstone. Many of these sandstones show evidence of deposition from waning currents. Facies 4 consists of trough cross-bedded sandstones with sets up to 4 m thick. Symmetrical ripples and bioturbation are ubiquitous. Bipolar palaeocurrent distributions are common to all facies and one mode is usually strongly dominant. Lateral facies variations and sedimentary structures suggest that deposition took place in a tide-dominated, offshore, shallow marine environment in which maximum sediment transport probably occurred when storm generated waves enhanced tidal currents. The four facies are thought to represent the deposits of various parts of tidal sediment transport paths such as exist in modern seas around Great Britain. Small scale coarsening upward sequences may represent the superposition of facies independently of changing water depth. Lack of information prevents a detailed palaeogeographic reconstruction. It is suggested that sand body shape is not accurately predictable.     

河北承德寒武系凤山组叠层石生物丘中的沉积组构

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。     

前寒武纪海侵砂岩中的微生物砂质碎片：以北京南口虎峪剖面大红峪组为例

碎屑岩中微生物形成的原生沉积构造,由于缺乏直接的微生物证据,其识别常常比较困难。位于北京西北郊的南口虎峪一带,古元古代晚期的大红峪组(1650～1600Ma),海侵体系域砂岩地层与高水位体系域砂泥质白云岩和叠层石白云岩组成了较为有规律的沉积相序特征,成为将大红峪组划分为三个三级层序的主要标志。在大洪峪组的海侵体系域砂岩层中,一种类似于碳酸盐岩中的“内碎屑”的奇特的砂质碎片,代表了前寒武纪海侵砂岩沉积面上曾经发育过微生物席;该砂质碎片与变余波痕和皱饰构造组成系列席底构造,特殊的形态和产出特点成为窥视前寒武纪砂岩中微生物席发育的一种典型标志。因此,南口虎峪剖面大红峪组海侵砂岩中的微生物砂质碎片及其相关的席底构造的发现,有益于今后对类似沉积构造的阐释与研究,特别是那些常常被厘定为前寒武纪古老的后生动物遗迹化石的沉积构造;同时也表明,在前寒武纪地层之中,除了要关注叠层石之类的微生物沉积构造以外,碎屑岩中也存在微生物活动的若干证据即席底构造(第五类原生沉积构造),这些特别的沉积构造对前寒武纪沉积环境重塑具有重要意义。     

中元古代叠层石—非叠层石碳酸盐岩层序地层序列及其沉积特征——以北京延庆千沟剖面高于庄组为例

北京延庆千沟剖面中元古代高于庄组为一套发育在海侵砂岩上的叠层石—非叠层石碳酸盐岩沉积序列,厚度千余米,包括4段:第一段(或称为官地亚组)主要为海侵砂岩地层;第二段(或称为桑树鞍亚组)为发育少量叠层石的含锰白云岩和灰质白云岩地层;第三段又称为张家峪垭组,为一套以均一石灰岩为主的地层序列,发育席底构造且贫乏叠层石;第四段(环秀寺亚组)以叠层石礁白云岩为特征。与蓟县剖面相比较,该剖面的高于庄组具有以下特点:(1)第一段厚度百余米的海侵砂岩地层不但表明了与下伏大红峪组之间存在较为明显的区域不整合面,而且与蓟县剖面厚数百米的叠层石白云岩地层形成明显的区别;(2)在第三段的非叠层石碳酸盐岩沉积序列中,未发现臼齿状构造,但发育丰富而典型的席底构造,而且以均一石灰岩为特征;(3)第四段的厚度为500余m,由罕见的叠层石礁序列所组成。这些特征表明,千沟剖面的高于庄组组成了一个复杂而有序的叠层石—非叠层石碳酸盐岩沉积序列,成为依据沉积相序列进行前寒武纪三级层序划分和二级层序合理归并的典型实例。更为重要的是,第四段中的叠层石生物礁和第三段的均一石灰岩序列的存在,反映了一些值得进一步研究的问题:如前寒武纪叠层石生物礁的沉积模式,非叠层石灰岩序列是否代表了一次叠层石衰减事件等等。     

南口虎峪中元古界大红峪组混积岩系的层序地层划分——海侵砂岩中的微生物席碎片简介

北京西北郊南口虎峪一带的中元古界长城系大红峪组发育完整,以一套混积岩系为特征。在南口虎峪剖面中,海侵体系域砂岩地层与高水位体系域砂泥质白云岩和叠层石白云岩组成了较有规律的层序地层相序,可以作为混积岩系层序地层划分的典型代表。在大红峪组的海侵体系域砂岩中,交余波痕、微生物形成的砂质碎片和皱饰构造表明了席底的发育,特别是其中所发育的微生物砂质碎片不但代表了碎屑岩中的一种特殊的“内碎屑”,而且其特殊的形态和产出特点成为窥视前寒武纪砂岩中席底发育的一种典型标志,从而有益于今后对类似沉积构造的阐释与研究;高水位体系域砂泥质白云岩中的纹理化构造似乎也是一种席底构造,它与其中的叠层石生物丘一起代表了前寒武纪海底微生物孤军作战的特殊生境。对该剖面大红峪组的初步研究表明,在前寒武纪地层中,除了要关注叠层石之类的微生物沉积构造以外,碎屑岩中也存在微生物活动的若干证据印席底构造（第五类原生沉积构造）,由此说明正是由于微生物新陈代谢的多样性才使其成为地球上无所不在及其无与伦比的巨大生物量。     

贺兰山地区中元古代微生物席成因构造

贺兰山中段中元古界黄旗口组石英砂岩中发现丰富的微生物席成因构造(MISS),包括由微生物席生长、破坏和腐烂过程形成的3种类型、9种不同形态的构造;与华北大红峪组发现的同类构造在成因类型与多样性方面具有很强的可对比性.砂岩中发育双向交错层理、冲洗层理、高角度单斜层理系和波痕,泥质粉砂岩夹层中发育波痕与泥裂,表明微生物席主要发育于潮间带上部至潮上带下部环境.MISS构造在华北地台长城系下部砂岩中的广泛存在表明在1.6 Ga前以蓝细菌为主的微生物群在环潮坪碎屑环境也很活跃.可能代表了微生物由海洋向陆地环境发展的过渡阶段.具光合作用功能的制氧蓝细菌的蓬勃发展可能是引发中元古代海洋化学条件发生转变、含氧量增高的重要原因,并为真核生物及宏观藻类的兴起创造了条件.研究表明,黄旗口组与华北大红峪组大致同时,反映了Columbia超大陆裂解期华北地台开始拉伸-张裂、缓慢沉降的构造古地理背景.     

豫西苗岭统馒头组二段皱饰构造与遗迹化石共生特征*

埃迪卡拉纪以来,微生物与后生动物之间呈此消彼长的关系,但在寒武纪苗岭世却出现了微生物成因沉积构造和后生动物扰动构造短暂共存的现象。笔者在豫西馒头组二段下部识别出包括皱饰构造与微生物席裂构造在内的2种微生物成因沉积构造,对皱饰构造与遗迹化石的共生关系进行了分类,建立了席上足辙迹(Monomorphichnus henanensis)与牧食迹(Jinningichnus badaowanensis)、席下水平漫游迹(Planolites montanus)、席下深层泥岩中生物扰动共3种微生物席与后生动物的共生模式和生态演化模型。上述研究表明,具有特殊环境耐受性的“机会主义”动物在食物来源较为宽松的潮坪环境中与微生物席共存,这种微生物席与后生动物短暂而“和谐”的共存关系不仅延续了埃迪卡拉纪双方的部分共生特征,且在以混合底为主导的显生宙生态环境中得到了进一步变化与发展。     

叠层石中的海绿石化和黄铁矿化:以天津蓟县中元古界铁岭组为例*

作为微生物碳酸盐岩的主要类型之一,叠层石是微生物席的主要建造物已成为共识。天津蓟县中元古界铁岭组二段叠层石生物礁灰岩发育,其中的细粒叠层石被前人解释为微生物席捕获碳酸盐泥的微生物建造物,使得其既不同于现代叠层石,也不同于显生宙尤其是寒武纪的叠层石。更为特殊的是,这些叠层石中的海绿石和黄铁矿代表着2种特殊的矿化作用,其中研究区普遍产出的黄铁矿,作为硫酸盐还原细菌的产物,是了解古代微生物的窗口;而发育在高能浅海的海绿石,产出环境不同于现代海绿石,不能作为慢速沉积环境的指示矿物,亦不具有沉积间断的地质意义。2种矿化作用表明铁岭组叠层石是由沉淀作用而非捕获碳酸盐泥形成,这为了解中元古代叠层石的形成和特征提供了一些有益的线索。     

The criteria for the biogeneicity of microbially induced sedimentary structures (MISS) in Archean and younger, sandy deposits

The identification of fossils or biogenic sedimentary structures in rocks of Archean age is difficult, because similar lithological features could rise from purely physical or chemical processes alone. Therefore it is important to define criteria that serve the secure definition of a fossil or structure in question as of biological origin. Such criteria have been established for stromatolites and microfossils.This contribution discusses the 6 criteria of biogeneicity of ‘microbially induced sedimentary structures’ (MISS). Those structures are found in sandy deposits of early Archean age to the present, and rise from the interaction of benthic microbiota with physical sediment dynamics. The six criteria for their biogeneicity are: (i) MISS occur in rocks of not more than lower greenschist facies; (ii) in stratigraphic sections, MISS correlate with turning points of regression–trangressions; (iii), MISS correlate with a characteristic depositional facies that enhances the development and the preservation of microbial mats; (iv), the distribution of MISS correlates with the ancient average hydraulic pattern; (v), the geometries and dimensions of fossil MISS correspond to that of the modern ones; (vi), the MISS include at least one of 9 specific microtextures.     

Primary sedimentary structures and MISS in Gulcheru quartzite along SW part of Cuddapah basin

Sedimentary structures are very useful in paleocurrent analysis and interpretation of siliciclastic shallow marine environment. These interesting sedimentary structures such as parallel bedding, cross bedding, ripples, and mud cracks as well as synaeresis cracks, are best studied in the field. They are formed by a variety of sedimentary processes, including fluid flow, sediment-gravity flow, soft-sediment deformation and biogenic activity. Gulcheru Formation has evidence of interaction of microbial communities with clastic sedimentation during Palaeoproterozoic time. Because of high porosity-permeability of siliciclastics of Gulcheru Formation, palaeontologists do not expect many fossils preserved in such rocks and thus they have been overlooked. Microbially induced sedimentary structures (MISS) are highlighted in the Gulcheru Formation. They are indicative of shallow marine environment. Gulcheru Formation shows alluvial fan to shallow marine shelf environments within a limited thickness of about ~ 110m, which indicates an alluvial plain coast where alluvial deposits are modified by wave forces.     

北京西郊下苇甸剖面寒武系崮山组叠层石生物丘的沉积组构

北京西郊下苇甸剖面的崮山组,属于寒武系第三统顶部,自下而上从陆棚相泥灰岩向上变浅至鲕粒滩相灰岩,组成一个淹没不整合型三级沉积层序。在该组上部的一层块状鲕粒滩相颗粒灰岩中,发育串珠状分布的、可以归为叠层石生物丘的穹窿状构造。这些叠层石生物丘,典型的地势隆起和突变的边界代表了明显的早期石化作用特征。叠层石生物丘中的柱状叠层石,为典型的泥晶相叠层石,其内部除了黏结较多的三叶虫生物碎屑外,还不均匀地分布着放射-纤维状方解石(或文石？)组成的底栖鲕粒。这些底栖鲕粒,以其较小的粒径、多样的类型、平滑但不连续的鲕粒圈层以及外部边缘的泥晶套等特征,明显区别于宿主岩石中的颗粒滩相悬浮鲕粒,而且表现出较为明显的与微生物活动相关的微组构。鉴于叠层石是典型的微生物席建造物,该叠层石生物丘特别的宏观和微观沉积组构还可以进一步将其归为较为典型的"微生物礁",从而成为研究中奥陶生物大辐射事件之前贫乏骨骼的浅海环境的沉积作用样式、以及更加深入理解这一特殊时期的微生物造礁作用特征提供了一个较为典型的实例。     

Messinian stromatolite-thrombolite associations,Santa Pola,SE Spain: an analogue for the Palaeozoic?

Stromatolite-thrombolite associations are the dominant facies forming large portions of the Santa Pola carbonate platform (SE Spain) during deposition of the Terminal Carbonate Complex (TCC). The TCC, the last period of marine sedimentation in the Western Mediterranean associated with the Messinian Salinity Crisis, comprises a NE-SW trending thrombolite reef with occasionally interlayered stromatolite horizons and a predominantply stromatolite and oolite facies in the back-reef area. The stromatolites are mainly dome shaped, but fine-columnar or wavy-undulose forms can occur. The stromatolites form huge bioherms, extending tens to hundreds of metres. They are finely laminated with alternating layers of dolomicrite and dolomicrospar. The dolomicrite layers appear to be a primary dolomite precipitate, whereas the dolomite crystals in the dolomicrospar layers apparently formed around a meta-stable nuclei which was subsequently dissolved or degraded. The low content of sand-sized particles in the stromatolitic layers indicates formation under low-energy conditions, possibly on a tidal flat. As reported from other areas in the Western Mediterranean, deposition of the TCC at Santa Pola was apparently cyclic, whereby stromatolites generally terminate each depositional cycle. Subtidal Conophyton stromatolites, possibly the only known occurrence younger than Palaeozoic, are, however, found on the reef slope at the base of the first TCC depositional cycle. The dolomitic nature of the unadulterated stromatolitic laminations and the association of stromatolites and thrombolites as platform builders were a common feature in the Early Palaeozoic but are unusual in post-Ordovician carbonate facies. We propose that the conditions during TCC deposition were very restricted, possibly reflecting an environment similar to that of the Early Palaeozoic.     

Relationships between cyclicity and stromatolite form in the Late Proterozoic Bitter Springs Formation, Australia

Stromatolite biostromes and bioherms in the lower two units of the Late Proterozoic Loves Creek Member of the Bitter Springs Formation represent shallowing upward and deepening upward sequences. In the central unit stromatolite form is governed by relative position in an asymmetric shallowing upward sequence. Ooid and/or peloid-intraclast grainstones and small, irregular bulbous and columnar stromatolites characterize the basal, transgressive portion of cycles. Domal, columnar and stratiform stromatolites comprise the bulk of the cycle. These forms accreted in a gradually shallowing epeiric sea. Domal stromatolites predominate in the deeper parts of cycles. Here synoptic relief gradually increases upwards. Columnar and stratiform stromatolites predominate in the shallower parts of cycles, where synoptic relief rapidly diminishes upwards. In thin-bedded dolo-mudstones at the tops of cycles the co-occurrence of desiccation cracks, tepee structures, scalloped dissolution surfaces, gypsum moulds and anhydrite nodule pseudomorphs provides evidence for subaerial exposure. In contrast, stromatolites in a unit at the base of the Loves Creek Member accreted during a gradual rise in sealevel. Stratiform, columnar and domal stromatolitic building blocks of the shallowing upward cycle are present in this deepening sequence, but only the lower half of the shallowing upward cycle is represented. Synoptic relief of the stromatolitic laminae gradually increases upward throughout the basal stromatolitic unit. Recognition of a deepening upward stromatolite sequence at the base of the Loves Creek Member, and a disconformity surface between this sequence and the underlying Gillen Member, permits palaeoenvironmental re-interpretation of the Loves Creek Member as a single ‘large scale’ sea-level cycle.     

Stromatolites in the Late Ordovician Eureka Quartzite: implications for microbial growth and preservation in siliciclastic settings

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.