鄂尔多斯盆地东缘保德地区上古生界层序地层与沉积相特征*

为了揭示鄂尔多斯盆地东缘层序地层与沉积相特征,以层序地层学和沉积学理论为指导,对鄂尔多斯盆地东缘保德扒楼沟剖面及周缘上古生界的层序与体系域界面类型、层序结构、沉积相类型及沉积演化进行研究。依据区域性不整合面、下切谷冲刷面、海侵方向转换面和区域性海退面等层序界面将研究区上古生界划分为7个三级层序,分别对应于本溪组、太原组2段、太原组1段、山西组、下石盒子组、上石盒子组和石千峰组。保德扒楼沟及周缘上古生界剖面发育16种岩石类型和8种岩石组合。区内上古生界发育障壁海岸相、碳酸盐岩台地相、辫状河相和曲流河相。SQ1-SQ3中低位体系域发育风化壳和潮道亚相,海侵体系域发育潮坪亚相和潟湖亚相,高位体系域发育碳酸盐岩台地相、潟湖亚相和潮坪亚相;SQ4-SQ7中低位体系域发育辫状河河床亚相,海侵体系域主要发育曲流河泛滥平原亚相,高位体系域主要发育多期曲流河河床亚相—堤岸亚相—泛滥平原亚相的演化序列。区内上古生界经历了由障壁海岸相和碳酸盐岩台地相向河流相的演化过程,沉积演化主要受物源供给、海平面变化和构造活动的控制。     

Early Permian transgressive–regressive cycles: Sequence stratigraphic reappraisal of the coal-bearing Barakar Formation,Raniganj Basin,India

The present research is an attempt to assess the Barakar Formation of the Raniganj Gondwana Basin, India, in the frame of fluvio-marine (estuarine) depositional systems using sequence stratigraphic elements. Analysis of predominant facies associations signify deposition in three sub-environments: (i) a river-dominated bay-head delta zone in the inner estuary, with transition from braided fluvial channels (FA-B1) to tide-affected meandering fluvial channels and flood plains (FA-B2) in the basal part of the succession; (ii) a mixed energy central basin zone, which consists of transitional fluvio-tidal channels (FA-B2), tidal flats, associated with tidal channels and bars (FA-B3) in the middle-upper part of the succession; and (iii) a wave-dominated outer estuary (coastal) zone (FA-B4 with FA-B3) in the upper part of the succession. Stacked progradational (P1, P2)–retrogradational (R1, R2) successions attest to one major base level fluctuation, leading to distinct transgressive–regressive (T–R) cycles with development of initial falling stage systems tract (FSST), followed by lowstand systems tract (LST) and successive transgressive systems tracts (TST-1 and TST-2). Shift in the depositional regime from regressive to transgressive estuarine system in the early Permian Barakar Formation is attributed to change in accommodation space caused by mutual interactions of (i) base level fluctuations in response to climatic amelioration and (ii) basinal tectonisms (exhumation/sagging) related to post-glacial isostatic adjustments in the riftogenic Gondwana basins.     

Sequence stratigraphy of coal‐bearing,high‐energy clastic units: The Maitland‐Cessnock‐Greta Coalfield and Cranky Corner Basin

Upper Carboniferous to Lower Permian sedimentary rocks extend along the periphery of the northern Sydney Basin, a sub‐basin of the Sydney‐Gunnedah‐Bowen Basin complex. The basin contains basal basalts and volcanic sediments deposited in a nascent rift zone. This rift zone was created through crustal thinning during trench rollback on the eastern edge of the New England Orogen. Thermal subsidence created accommodation for predominantly marine Dalwood Group sediments. Clastic sedimentation then occurred in the Maitland‐Cessnock‐Greta Coalfield and Cranky Corner Basin during the Early Permian. This occurred on a broad shelf undergoing renewed thermal subsidence on the margin of a rift flank of the Tamworth Belt of the southern New England Orogen. Braidplain fans prograded or aggraded in two depositional sequences. The first sequence commences near the top of the Farley Formation and includes part of the Greta Coal Measures, while the second sequence includes the majority of the Greta Coal Measures and basal Branxton Formation. Thin, areally restricted mires formed during interludes in a high sedimentation regime in the lowstand systems tracts. As base‐level rose, areally extensive mires developed on the transgressive surface of both sequences. A paludal to estuarine facies changed to a shallow‐marine facies as the braidplain was transgressed. The transgressive systems tracts continued to develop with rising relative sea‐level. Renewed uplift in the hinterland resulted in the erosion of part of the transgressive systems tract and all of the highstand systems tract of the lower sequence. In the upper sequence a reduction in relative sea‐level rise saw the development of a deltaic to nearshore shelf highstand systems tract. Extensional dynamics caused a fall in relative base‐level and the development of a sequence boundary in the Branxton Formation. Finally, renewed thermal subsidence created accommodation for the overlying, predominantly marine Maitland Group.     

山东黄县盆地古近系李家崖组含煤岩系沉积相特征及演化

山东黄县盆地是中国东部一个重要的煤和油页岩共生盆地,古近系李家崖组是盆地主要的含煤岩系发育层段。根据层序地层学理论,建立了古近系层序地层格架;依据钻测井、岩心资料划分了李家崖组的沉积相类型,编制了分体系域的沉积相图。主要结论如下:(1)李家崖组发育湖泊、辫状河三角洲以及扇三角洲3种沉积相类型。(2)层序Ⅰ低水位体系域以辫状河三角洲相为主,湖扩展体系域以扇三角洲相和湖泊相为主,高水位体系域以扇三角洲相为主;层序Ⅱ低水位体系域以辫状河三角洲相为主,湖扩展体系域以扇三角洲相和湖泊相为主,高水位体系域以湖泊相为主。(3)层序Ⅰ发育时期: 低水位期盆地初始形成—湖扩展期盆地扩张—高水位期盆地萎缩;层序Ⅱ发育时期: 低水位期盆地再次缓慢扩张—湖扩展期盆地加速扩张—高水位期盆地萎缩消亡。     

尼日尔Termit盆地上白垩统Madama组地震相识别与沉积相演化分析

以层序地层学及沉积学理论为指导,综合运用测井、录井以及地震资料,将尼日尔Termit盆地上白垩统Madama组划分为一个三级层序(MS),并进一步识别出低位体系域、海侵体系域以及高位体系域。在等时层序地层格架内,识别出前积反射地震相、河道充填反射地震相、平行-亚平行反射地震相以及杂乱反射地震相等四种类型,并识别出辫状河三角洲的沉积相类型。认为层序MS的低位体系域主要发育辫状河三角洲前缘亚相,高位体系域则主要发育辫状河三角洲平原亚相。Madama组整体表现为一个海退的沉积演化过程。     

准噶尔盆地莫索湾地区白垩系清水河组沉积演化与有利砂体展布

以三维地震、钻测井、岩心、测试化验等资料为基础,对准噶尔盆地莫索湾地区白垩系清水河组特别是“底砂岩段”重点油气储集层进行层序地层划分、沉积特征和砂体展布研究。认为:(1)清水河组发育高位体系域、湖侵体系域和低位体系域;其中,低位体系域主要发育浅水辫状河三角洲相,湖侵体系域发育滨浅湖-半深湖相,而高位体系域则发育浅水曲流河三角洲相。(2)“底砂岩段”中发育水下分流河道、河口坝、席状砂和分流间湾4种沉积微相类型;“底砂岩段”位于受北部物源控制的浅水辫状河三角洲前缘,可分为内前缘和外前缘;(3)结合区域沉积背景建立了清水河组浅水三角洲沉积微相模式,整体上,清水河组沉积演化过程为一套完整的湖平面升降演化沉积旋回。     

准噶尔盆地东部地区八道湾组层序地层及油气勘探有利区带预测

运用层序地层学与沉积学的原理和方法,建立滴水泉地区侏罗系八道湾组层序地层格架,划分沉积相,在此基础上分析层序充填及沉积演化特征,预测研究区岩性油气藏的类型及分布。研究结果表明:八道湾组为“一个半”层序,包括5个体系域。整体经历了一个先退积、后进积、再退积的过程。研究区发育辫状河、辫状河三角洲和湖泊3种沉积相类型、5种沉积亚相类型和10种沉积微相类型。JSQ1层序低位体系域以辫状河沉积为主,湖侵体系域主要发育滨浅湖沉积,高位体系域以辫状河三角洲沉积为主;JSQ2层序低位体系域主要发育辫状河三角洲沉积,而湖侵体系域以滨浅湖沉积为主。滴水泉地区八道湾组发育的有利储集砂体是辫状河和辫状河三角洲砂体,主要发育于低位和高位体系域。研究区八道湾组沟谷型古地貌可与JSQ1低位体系域广泛分布的辫状河道砂体组合形成地层-岩性圈闭,是研究区最有利的勘探目标。     

黑龙江七星河含煤盆地古近纪-新近纪沉积相及层序地层特征

黑龙江省东部七星河盆地是一新生代聚煤盆地,其含煤地层为古近系宝泉岭组、新近系富锦组。宝泉岭组由各级砂岩、泥岩、炭质泥岩以及褐煤组成,发育滨浅湖相、深-半深湖相、三角洲平原相,属于湖泊沉积体系、三角洲沉积体系。富锦组主要由泥岩、粉砂岩、中砂岩、含砾粗砂岩及煤层、炭质泥岩、硅藻岩组成,发育滨浅湖相、扇三角洲平原相,分别属于湖泊沉积体系和扇三角洲沉积体系。层序SI相当于宝泉岭组,发育低位体系域、湖侵体系域和高位体系域,煤层主要发育高位体系域中后期,成煤环境以滨浅湖淤积沼泽为主。层序SII相当于富锦组,主要发育湖侵体系域、高位体系域,局部地区发育低位体系域,煤层亦主要发育高位体系域中后期,成煤环境以扇三角洲淤积沼泽和滨浅湖淤积沼泽为主。层序SI、SII的高位体系域中后期,盆地基底沉降速率和物源供给处于相对平衡状态,主要发育了扇三角洲淤积沼泽、滨浅湖和滨浅湖淤积沼泽环境,发育可采煤层。     

Early Jurassic palaeoenvironments in the Surat Basin,Australia – marine incursion into eastern Gondwana

Interpretations of palaeodepositional environments are important for reconstructing Earth history. Only a few maps showing the Jurassic depositional environments in eastern Australia currently exist. Consequently, a detailed understanding of the setting of Australia in Gondwana is lacking. Core, wireline logs, two-dimensional and three-dimensional seismic from the Precipice Sandstone and Evergreen Formation in the Surat Basin have been used to construct maps showing the evolution of depositional environments through the Early Jurassic. The results indicate the succession consists of three third-order sequences (Sequence 1 to Sequence 3) that were controlled by eustatic sea level. The lowstand systems tract in Sequence 1 comprises braidplain deposits, confined to a fairway that parallels the basin centre. The strata were initially deposited in two sub-basins, with rivers flowing in different orientations in each sub-basin. The transgressive systems tract of Sequence 1 to lowstand systems tract of Sequence 3 is dominated by fluvio–deltaic systems infilling a single merged basin centre. Finally, the transgressive and highstand systems tracts of Sequence 3 show nearshore environments depositing sediment into a shallow marine basin. In the youngest part of this interval, ironstone shoals are the most conspicuous facies, the thickness and number of which increase towards the north and east. This study interprets a corridor to the open ocean through the Clarence–Moreton Basin, or the Carpentaria and Papuan basins, evidence of which has been eroded. These results challenge a commonly held view that eastern Australia was not influenced by eustasy, and propose a more dynamic palaeogeographic setting comprising a mixture of fluvial, deltaic and shallow marine sedimentary environments. This work can be used to unravel the stratigraphic relationships between Mesozoic eastern Australian basins, or in other basins globally as an analogue for understanding the complex interplay of paralic depositional systems in data poor areas.     

塔里木盆地塔中-塔北志留系层序地层

随着近年来塔里木盆地勘探开发的逐步深入,志留系地层已经成为众多学者的研究热点。本文应用层序地层研究方法,利用钻井、测井、地震及实验分析资料,通过对岩石地层、测井地层、生物地层、地震地层等资料的综合分析,将塔里木盆地志留系地层划分为3个三级层序,SQ1对应柯坪塔格组下段,SQ2对应柯坪塔格组中上段,SQ3对应塔塔埃尔塔格组。每个层序由海侵体系域和高位体系域组成,不发育低位体系域。对层序格架内的沉积类型和沉积相展布进行分析,认为主要发育扇三角洲相-有障壁潮坪相-浅海相。     

鄂尔多斯盆地中南部上古生界层序与岩相古地理演化*

为明确鄂尔多斯盆地中南部上古生界层序特点与岩相古地理演化规律,利用周缘野外露头和盆地钻井测井相特征,分析层序界面、体系域界面的岩性、古构造及海侵方向变化特征,总结层序发育特点与岩相古地理演化规律。结果表明: 不同风化序列的区域性不整合面及海侵方向转换面为二级层序界面,区域性海退面、下切冲刷面及陆上暴露面为三级层序界面; 潮间带砂坪及近岸相海侵含砾砂岩顶为海侵面,最大海侵面发育灰岩、泥页岩及煤层,是海侵体系域与高位体系域分界面; 上古生界包括二级层序2个: MSQ1、MSQ2,三级层序6个: SQ1、SQ2、SQ3、SQ4、SQ5、SQ6,其中SQ1—SQ2发育水进体系域与高位体系域,不发育低位体系域,SQ1为潟湖—障壁海岸沉积体系,SQ2为泥炭坪—泥坪相潮坪沉积;SQ3—SQ6发育完整的低位—海侵—高位体系域,SQ3发育区域性海退进积海陆过渡相三角洲沉积,SQ4早期为低位体系域下切冲蚀砂体,晚期沉积古环境由温暖湿润还原环境演变为炎热干燥的氧化环境,SQ5—SQ6早中期为氧化环境三角洲沉积,SQ6晚期为高位体系域具海侵夹层的潮坪相沉积。研究为鄂尔多斯盆地及其他盆地层序与岩相古地理演化提供理论依据。     

川西坳陷中段须四段层序地层格架内沉积特征

为了深入认识川西坳陷中段须四段层序地层格架内沉积特征,综合利用野外露头、地震、岩心、测/录井、分析测试等资料对其进行了系统分析。结果表明须四段为一个三级层序,根据层序界面特征划分出低位体系域、湖侵体系域和高位体系域,并建立了等时层序地层格架。依据沉积相标志识别出冲积扇、辫状河、辫状河三角洲和湖泊4种相类型,明确了层序地层格架内沉积相平面展布及纵向演化特征：平面上,短轴物源自龙门山山前依次发育冲积扇、辫状河、辫状河三角洲和湖泊相,长轴物源主要发育辫状河三角洲前缘沉积,长短轴物源在合兴场-德阳-马井-新繁镇一带地区交汇;纵向上,低位体系域和高位体系域时期以辫状河三角洲前缘沉积为主,水下分支河道砂体纵向叠置、横向连片、分布广泛,湖侵体系域时期以滨浅湖沉积为主。建立了层序-沉积充填模式,指出低位体系域和高位体系域时期的长轴物源和长短轴物源交汇区辫状河三角洲前缘水下分支河道砂体是研究区优质储层发育区。     

德阳须家河组四段沉积相特征和砂体分布规律

孝泉—新场—合兴场地区上三叠统须家河组四段以发育扇三角洲沉积体系为主,其砂体成因类型为扇三角洲前缘水下辫状分流河道(含砾)中—粗粒砂岩夹少量碎屑流沉积砾岩。须家河组四段可划分为1个长期、3个中期和18个短期基准面旋回层序,主要砂体合并为6套砂组。各砂组分布与由基准面变化引起的可容纳空间和沉积物供给量比值密切相关:低位体系域沉积期,基准面上升缓慢,沉积物供给(远)大于可容纳空间,沉积作用以主动进积为主,砂体不断向湖盆方向推进;湖侵体系域沉积期,基准面快速上升,沉积物供给量逐渐减少而(远)小于可容纳空间,沉积作用由进积逐渐转入加积和退积;高位体系域沉积期,基准面由缓慢上升逐渐进入到快速下降,可容纳空间由缓慢增加突变为迅速减小,而沉积物供给由小于或略等于可容纳空间逐渐变为(远)大于可容纳空间,沉积作用由弱进积、加积迅速变为强迫进积。     

胜利油区石炭二叠系含煤地层层序地层学初探

胜利油区石炭二叠系含煤地层包括中石炭统本溪组、上石炭统太原组和下二叠统山西组。可识别出潮坪沉积、障壁岛湖沉积和三角洲沉积三种沉积类型。根据区域地质及古生物资料,确定了三个等时面,划分出２个层序１４个准层序,每个层序包括低位体系域、海侵体系域及高位体系域,而以高位体系域最发育。纵观整个含煤地层的沉积演化过程,本溪组沉积期以滨浅海相为主;太原组沉积期为海陆交替相;山西组沉积期以三角洲相为主,总体表现为海退层序。     

塔里木盆地东南部石炭系,二叠系沉积与层序特征

塔里木盆地东南部中古炭统一下二叠统是一个顶底为Ⅰ类不整合所限定的二级沉积层序。该层序沉积期，塔里木盆地东南部存在三个古陆，两个浅海海峡，一个半深海斜坡。随着海面上升－静止－下降于不同部位形成了不同沉积体系及组合。海进体系域由中上石炭统的滨岸破坏性三     

陆相前陆盆地沉积充填与层序地层模式探讨——以库车前陆盆地为例

以库车前陆盆地为例,对陆相前陆盆地的形成、沉积充填与层序地层结构、不整合面与层序界面、层序地层组成与其模式、生储盖组合与岩性地层圈闭等关键问题进行了探讨。认为前陆层序是盆缘构造运动的响应,由低位(冲积)体系域、湖侵体系域、高位体系域组成。前陆盆地层序界面表现为构造或沉积不整合面,代表了一次构造幕的发生,其层序地层样式是盆缘造山带构造楔推进作用的结果,是盆地演化的不同阶段的响应,反映了构造运动由强到弱的间歇变化。前陆层序界面代表了沉积结构的大转换,之下为构造稳定阶段的湖相泥岩或膏泥岩,之上为代表构造运动的冲积扇—扇三角洲相的巨厚磨拉石沉积充填。在构造活动期和静止期,盆地不同位置形成不同的沉积充填和地层结构特点。构造活动期以低位(冲积)体系域为主,在毗邻造山带侧以巨厚的冲积扇-扇三角洲-辫状河三角洲相等冲积沉积物为主;构造静止期以湖侵体系域为主,为广泛的河流-湖泊相沉积。沉积厚度从靠近冲断带侧向盆地内逐渐变小。陆相前陆盆地的生储盖组合配置好,储集体广泛分布于低位、湖侵和高位体系域中,以辫状河三角洲和滨湖相为主。其岩性地层圈闭主要分布在前缘斜坡带上,包括沿古隆起边缘的地层超覆不整合圈闭和地层削蚀不整合圈闭,将会成为今后油气勘探的新领域。     

二连盆地吉尔嘎朗图凹陷下白垩统赛汉塔拉组层序地层及聚煤特征

二连盆地吉尔嘎朗图凹陷是一个陆相断陷聚煤盆地,下白垩统赛汉塔拉组是其主要含煤地层,作者利用岩心、钻孔资料对其岩相类型、沉积相、层序地层及聚煤作用特征进行研究。(1)赛汉塔拉组主要由砂砾岩、砂岩、粉砂岩、泥岩、碳质泥岩及厚层褐煤组成,发育扇三角洲平原相、扇三角洲前缘相、辫状河三角洲平原相、辫状河三角洲前缘相、滨浅湖相,分别属于扇三角洲沉积体系、辫状河三角洲沉积体系和湖泊沉积体系。(2)识别出2种层序界面:不整合面和下切谷冲刷面,将赛汉塔拉组划分为2个三级层序。从层序Ⅰ到层序Ⅱ,煤层厚度逐渐增大,聚煤作用逐渐增强。(3)在滨浅湖环境下厚煤层主要形成于湖侵体系域早期,在扇/辫状河三角洲环境下厚煤层主要形成于湖侵体系域晚期,煤层厚度在凹陷中部最大,向西北和东南方向均变小。聚煤作用明显受基底沉降作用影响,可容空间增加速率与泥炭堆积速率相平衡,从而形成了区内巨厚煤层。     

二龙山含煤盆地中新世富锦组沉积相及层序地层特征

黑龙江东部二龙山盆地是一新生代陆相聚煤盆地,中新世富锦组是其含煤地层。通过对富锦组沉积相、层序地层和聚煤作用特征的研究,可以看出:富锦组主要由凝灰质粉砂岩及中细砂岩、凝灰质砾岩及褐煤组成,发育滨浅湖相、深-半深湖相、冲积扇扇根相、扇中相及沼泽相,分别属于湖泊沉积体系和冲积扇沉积体系;富锦组是一个以区域不整合面为上下界的三级层序,其低位体系域对应底部砾岩段,湖侵体系域对应下部砂岩段和中部含煤段,高位体系域对应上部砂岩段;研究区煤层形成于湖侵体系域末期,且以盆地中部煤层厚度最大,向西北和西南方向煤层均变薄;聚煤作用明显受基底沉降作用影响,在湖侵体系域末期基底稳定沉降阶段,可容空间增加速率与泥炭堆积速率相平衡,从而形成了区内巨厚煤层。      

Turbidites in the Upper Carboniferous Ross Formation, western Ireland: reconstruction of a channel and spillover system

ABSTRACT The Upper Carboniferous deep‐water rocks of the Shannon Group were deposited in the extensional Shannon Basin of County Clare in western Ireland and are superbly exposed in sea cliffs along the Shannon estuary. Carboniferous limestone floors the basin, and the basin‐fill succession begins with the deep‐water Clare Shales. These shales are overlain by various turbidite facies of the Ross Formation (460 m thick). The type of turbidite system, scale of turbidite sandstone bodies and the overall character of the stratigraphic succession make the Ross Formation well suited as an analogue for sand‐rich turbidite plays in passive margin basins around the world. The lower 170 m of the Ross Formation contains tabular turbidites with no channels, with an overall tendency to become sandier upwards, although there are no small‐scale thickening‐ or thinning‐upward successions. The upper 290 m of the Ross Formation consists of turbidites, commonly arranged in thickening‐upward packages, and amalgamated turbidites that form channel fills that are individually up to 10 m thick. A few of the upper Ross channels have an initial lateral accretion phase with interbedded sandstone and mudstone deposits and a subsequent vertical aggradation phase with thick‐bedded amalgamated turbidites. This paper proposes that, as the channels filled, more and more turbidites spilled further and further overbank. Superb outcrops show that thickening‐upward packages developed when channels initially spilled muds and thin‐bedded turbidites up to 1 km overbank, followed by thick‐bedded amalgamated turbidites that spilled close to the channel margins. The palaeocurrent directions associated with the amalgamated channel fills suggest a low channel sinuosity. Stacks of channels and spillover packages 25–40 m thick may show significant palaeocurrent variability at the same stratigraphic interval but at different locations. This suggests that individual channels and spillover packages were stacked into channel‐spillover belts, and that the belts also followed a sinuous pattern. Reservoir elements of the Ross system include tabular turbidites, channel‐fill deposits, thickening‐upward packages that formed as spillover lobes and, on a larger scale, sinuous channel belts 2·5–5 km wide. The edges of the belts can be roughly defined where well‐packaged spillover deposits pass laterally into muddier, poorly packaged tabular turbidites. The low‐sinuosity channel belts are interpreted to pass downstream into unchannellized tabular turbidites, equivalent to lower Ross Formation facies.     

雪峰古陆边缘上石炭统露头层序地层

雪峰古陆边缘沅陵地区的上石炭统岩性特殊,以灰岩为主平白云质灰岩、砾屑灰岩与砾岩、砂岩相互成层,交替出现,因此,相对海平面升降变化在这种类型沉积中表现明显,利用层序地层的研究。上石炭统为１个三级层序,底部以Ｉ型层序与震旦系留茶坡组硅质岩接触;顶部仍以Ｉ型层序边界与下二叠统黔阳组成邻。包括低水位体系域、海进体系域和高水位体系域;依据准层序的叠是分为两个准层序组,即海进体系域和高水位体系域。