扬子北缘黄陵地区晚中生代盆地演化及其构造意义

扬子北缘黄陵地区古构造应力场于晚中生代经历发生了重大转变,是扬子板块与华北板块在三叠纪碰撞造山之后陆内构造变形的体现。由黄陵背斜周缘晚中生代盆地充填记录所反映出这一变革的起始时间为中侏罗世晚期。早侏罗世-中侏罗世早期,盆地内沉积了以桐竹园组为代表的河流-湖泊相岩层,由沉积碎屑成分和古水流统计所得出的物源区为北部的秦岭地区,黄陵背斜上部可能也接受了碎屑沉积;中侏罗世晚期-晚侏罗世,沉积中心发生了改变,表现为仅仅在黄陵背斜西侧的秭归盆地内有所保存,沉积环境以曲流河到辫状河流和三角洲为主,物源区则局限于黄陵背斜;早白垩世初期,周坪盆地和宜昌盆地为沉积中心,近缘冲积扇和辫状河流体系占据主体,物源区依然为黄陵地区,两盆地在黄陵背斜南缘可能相连,黄陵背斜上部的原下侏罗统被剥蚀;早白垩世晚期-晚白垩世,远安盆地逐渐发育,盆地西缘为冲积扇-辫状河流体系,中、 东部则以曲流河-湖泊沉积环境为主体,并间有干旱沙漠环境。原型盆地再造结果显示,早侏罗世-中侏罗世早期盆地展布具有近东西向特点,古地貌总体呈现出北部为山脉、 南部为盆地的格局;中侏罗世晚期以来,盆地呈近南北向,黄陵背斜逐渐形成山脉,盆地位于其东西两侧。两期盆地沉积特征反映了扬子北缘古构造应力场由近南北向转变为近东西向的过程。     

Early–Middle Jurassic evolution of the northern Yangtze foreland basin: a record of uplift following Triassic continent–continent collision to form the Qinling–Dabieshan orogenic belt

The northern Yangtze foreland basin system was formed during the Mesozoic continental collision between the North and South China plates along the Mianlue suture. In response to the later phase of intra-continental thrust deformation, an extensive E–W-trending molasse basin with river, deltaic, and lake deposits was produced in front of the southern Qinling–Dabieshan foreland fold-and-thrust belt during the Early–Middle Jurassic (201–163 Ma). The basin originated during the Early Jurassic (201–174 Ma) and substantially subsided during the Middle Jurassic (174–163 Ma). A gravelly alluvial fan depositional system developed in the lower part of the Baitianba Formation (Lower Jurassic) and progressively evolved into a meandering river fluvial plain and lake systems to the south. The alluvial fan conglomerates responded to the initial uplift of the southern Qinling–Dabieshan foreland fold-and-thrust belt after the oblique collision between the Yangtze and North China plates during the Late Triassic. The Qianfoya Formation (lower Middle Jurassic) mainly developed from shore-shallow lacustrine depositional systems. The Shaximiao Formation (upper Middle Jurassic) predominantly consists of thick-bedded braided river delta successions that serve as the main body of the basin-filling sequences. The upward-coarsening succession of the Shaximiao Formation was controlled by intense thrusting in the southern Qinling–Dabieshan fold-and-thrust belt. Palaeogeographic reconstructions indicated an extensive E–W foredeep depozone along the fold-and-thrust belt during the Middle Jurassic (174–163 Ma) that was nearly 150 km wide. The depozone extended westward to the Longmenshan and further east to the northern middle Yangtze plate. The northern Yangtze foreland basin was almost completely buried or modified by the subsequent differential thrusting of Dabashan and its eastern regions (Late Jurassic to Cenozoic).     

Detrital zircon geochronology analysis of the Late Mesozoic deposition in the Turpan‐Hami basin: Implications for the uplift history of the Eastern Tian Shan,north‐western China

Analysing the provenance changes of synorogenic sediments in the Turpan‐Hami basin by detrital zircon geochronology is an efficient tool to examine the uplift and erosion history of the easternmost Tian Shan. We present detrital zircon U‐Pb analysis from nine samples that were collected within marginal lacustrine Middle‐Late Jurassic and aeolian‐fluvial Early Cretaceous strata in the basin. Middle‐Early Jurassic (159–172 Ma) zircons deriving from the southern Junggar dominated the Middle Jurassic sample from the western Turpan‐Hami basin, whereas Permian‐Carboniferous (270–330 Ma) zircons from the Bogda mountains were dominant in the Late Jurassic to Early Cretaceous samples. Devonian‐Silurian (400–420 Ma) and Triassic (235–259 Ma) zircons from the Jueluotage and Harlik mountains constituted the subordinate age groups in the Late Jurassic and Early Cretaceous samples from the eastern basin respectively. These provenance transitions provide evidence for uplift of the Bogda mountains in the Late Jurassic and the Harlik mountains since the Early Cretaceous.     

准噶尔盆地南缘侏罗纪沉积相演化与盆地格局

通过对准噶尔盆地南缘侏罗系5条剖面的沉积特征对比,结合钻井资料和地震资料,确定了准噶尔盆地南缘侏罗纪盆地边界、沉积相演化及盆地格局。头屯河剖面和后峡剖面的沉积相对比及古流向测量表明二者在早、中侏罗世形成于同一沉积体系。在早、中侏罗世,沉积相逐渐从以辫状河-三角洲-湖泊相为主过渡到以河流相-湖泊相为主,沉积水体逐渐变浅;其中三工河组沉积时期盆地沉积范围达到最大,西山窑组沼泽相发育,车排子-莫索湾凸起自西山窑组沉积时期开始形成;早、中侏罗世的盆地边界至少位于后峡以南附近,此时不存在地理分割明显的天山山脉。晚侏罗世－早白垩世早期,沉积相从辫状河-滨浅湖相为主迅速演变为以辫状河-冲积扇相为主。在此期间盆地边界明显向北迁移,天山山脉明显隆升并造就天山南北沉积环境的巨大差异,博格达山构成盆地南缘的又一重要物源体系。     

十万大山盆地中生代沉积充填特征及其演化

十万大山盆地是印支期以来发展起来的中、新生代陆相盆地。盆地自晚三叠世-白垩纪具有比较典型的碰撞前陆盆地特征。该时期盆地的地层、沉积相类型及时空展布、沉积旋回和沉积边界的迁移具有明显的规律性。盆地的沉积地层多以山麓相、河流相为主,尚有少量滨浅湖相沉积,具近物源沉积特征;沉积相展布自晚三叠世至白垩纪具有沉积范围小-大-小-大的规律;沉积旋回呈现了浅-深-浅的规律;沉积边界和沉降中心不断向北和北东方向迁移。这些规律反映了十万大山前陆盆地的构造演化,即晚三叠世碰撞逆冲活动启动,盆地进入前陆盆地发育阶段;早、中侏罗世造山活动强烈,盆地沉降幅度大,物源供应充足;晚侏罗世造山活动减缓,盆地相对萎缩;白垩纪造山活动再次加强,盆地处于第二个发育期。     

鄂尔多斯盆地西缘前陆盆地构造-沉积响应

鄂尔多斯盆地西缘前陆地区在晚三叠世-中侏罗世经历了印支运动和燕山运动早期的影响,西缘整体抬升,西南和西北两个造山带开始显现,古地理为继承性的南湖北河格局,此时秦岭造山带的形成使西南地区由滨海相向湖沼相过渡。晚侏罗世-早白垩世是西缘地区前陆盆地形成时期,燕山中期逆冲推覆作用强烈,该区地层角度不整合发育,沉积记录的响应表现为南北向隆坳相间的前陆盆地格局,有别于前陆盆地形成始于晚三叠世的认识。晚白垩世-新生代是喜山运动的后期改造时期,地层角度不整合发育,沉积响应为平原沼泽相沉积。     

塔里木盆地早白垩世沉积相特征与古地理

根据大量的钻井和露头资料,对塔里木盆地早白垩世沉积相特征和古地理进行了研究。塔里木盆地下白垩统主要发育冲积扇-扇三角洲、辫状河三角洲、氧化宽浅湖泊等3种沉积体系,包括陆相冲（洪）积扇、扇三角洲、辫状河三角洲、滨浅湖等沉积相,分布于下白垩统不同层位。塔里木盆地早白垩世主要包括塔东北和塔西南两大沉积区,总体为干旱氧化的内陆拗陷分割盆地。在塔东北沉积大区,早白垩世早期卡普沙良群沉积物受周缘4大物源区控制,为多物源的氧化宽浅湖盆环境,古地势呈“南高北低、东高西低”,盆地边缘以冲（洪）积扇、扇三角洲、辫状河三角洲相为主,盆地内部为滨浅湖亚相。早白垩世晚期巴什基奇克组沉积时期,塔里木盆地周缘进入一个新的构造活动期,古气候更加炎热干旱,氧化宽浅湖盆消失。在塔东北沉积大区,盆地受周缘4个主要物源区影响,以广泛分布的冲积扇-辫状河三角洲沉积体系占主体,盆地内部普遍为辫状河三角洲前缘-滨浅湖亚相沉积。在塔西南沉积大区,早白垩世克孜勒苏群沉积时期古地势呈“东高西低”,受北部喀什北山前和西南部古昆仑山2个物源区的控制,沉积物沿古昆仑山前呈狭长的条带状分布,沉积厚度自西向东减薄,主要是一套冲积扇-扇三角洲相和滨浅湖亚相沉积。     

柴达木盆地北缘东部侏罗系发育特征

侏罗系是柴达木盆地主力生油层,主要分布于盆地北缘。通过对柴北缘侏罗系标志层、岩性特征和沉积体系的综合研究,明确了主要露头剖面侏罗纪不同时期的沉积相类型。本区侏罗系主要发育 5 种类型沉积相,包括冲积扇、辫状河、扇三角洲、辫状河三角洲和湖泊,相带的展布和古地理演化均与区域构造运动密切相关。根据侏罗系内部及其与上下地层的接触关系和沉积旋回演化,柴达木盆地北缘东部经历了早--中侏罗世断陷湖盆沉积到晚侏罗世挤压坳陷沉积两大沉积演化阶段。     

Sedimentary Characteristics of the Cretaceous in the Songliao Basin

The rupture of the lithosphere in Late Jurassic brought about the eruption of basaltic magma in the Songliao Basin. The evolution of the basin in Cretaceous progressed through six stages: pre-rift doming, extensional fracturing, fault subsidence, fault downwarping, downwarping and shringkage, resulting in the deposition of terrstrial facies nearly 10,000 m thick. There are different depositional sequences in these stages: the depositional period of the Early Cretaceous Shahezi and Yincheng Formations is the development stage of the down-faulted basin, forming a volcanic rock-alluvial fan-fan delta-lacustrine (intercalated with episodic turbidites)-swamp facies sequences; the period of the Early Cretaceous Dengluku Formation is the transformation stage of fault subsidence into fault downwarping of the basin, forming a sequence mainly of alluvial plain-lacustrine facies; the depositional period of the Early Cretaceous Quantou Formation-Late Cretaceous Nenjiang Formation is the downwarping stage of the basin, forming an alluvial plain-delta-lacustrine facies sequence; the period of the Late Cretaceous Sifangtai Formation-Mingshui Formation is the shringkage stage of the basin, forming again a sequence mainly of alluvial plain-alluvial fan and small relict lacustrine facies. These vertical depositional sequences fully display the sedimentary characteristics of a failed continental rift basin. Many facts indicate that the two large-scale lake invasions, synchronous with the global rise of sea level, which took place in the downwarping stage of the basin development, led to the connection between the lake and sea.     

Sedimentary response to the paleogeographic and tectonic evolution of the southern North China Craton during the late Paleozoic and Mesozoic

With the aim of constraining the influence of the surrounding plates on the Late Paleozoic–Mesozoic paleogeographic and tectonic evolution of the southern North China Craton (NCC), we undertook new U–Pb and Hf isotope data for detrital zircons obtained from ten samples of upper Paleozoic to Mesozoic sediments in the Luoyang Basin and Dengfeng area. Samples of upper Paleozoic to Mesozoic strata were obtained from the Taiyuan, Xiashihezi, Shangshihezi, Shiqianfeng, Ermaying, Shangyoufangzhuang, Upper Jurassic unnamed, and Lower Cretaceous unnamed formations (from oldest to youngest). On the basis of the youngest zircon ages, combined with the age-diagnostic fossils, and volcanic interlayer, we propose that the Taiyuan Formation (youngest zircon age of 439 Ma) formed during the Late Carboniferous and Early Permian, the Xiashihezi Formation (276 Ma) during the Early Permian, the Shangshihezi (376 Ma) and Shiqianfeng (279 Ma) formations during the Middle–Late Permian, the Ermaying Group (232 Ma) and Shangyoufangzhuang Formation (230 and 210 Ma) during the Late Triassic, the Jurassic unnamed formation (154 Ma) during the Late Jurassic, and the Cretaceous unnamed formation (158 Ma) during the Early Cretaceous. These results, together with previously published data, indicate that: (1) Upper Carboniferous–Lower Permian sandstones were sourced from the Northern Qinling Orogen (NQO); (2) Lower Permian sandstones were formed mainly from material derived from the Yinshan–Yanshan Orogenic Belt (YYOB) on the northern margin of the NCC with only minor material from the NQO; (3) Middle–Upper Permian sandstones were derived primarily from the NQO, with only a small contribution from the YYOB; (4) Upper Triassic sandstones were sourced mainly from the YYOB and contain only minor amounts of material from the NQO; (5) Upper Jurassic sandstones were derived from material sourced from the NQO; and (6) Lower Cretaceous conglomerate was formed mainly from recycled earlier detritus.The provenance shift in the Upper Carboniferous–Mesozoic sediments within the study area indicates that the YYOB was strongly uplifted twice, first in relation to subduction of the Paleo-Asian Ocean Plate beneath the northern margin of the NCC during the Early Permian, and subsequently in relation to collision between the southern Mongolian Plate and the northern margin of the NCC during the Late Triassic. The three episodes of tectonic uplift of the NQO were probably related to collision between the North and South Qinling terranes, northward subduction of the Mianlue Ocean Plate, and collision between the Yangtze Craton and the southern margin of the NCC during the Late Carboniferous–Early Permian, Middle–Late Permian, and Late Jurassic, respectively. The southern margin of the central NCC was rapidly uplifted and eroded during the Early Cretaceous.     

北羌塘乌兰乌拉湖地区白垩纪岩石地层及沉积环境

详细描述了北羌塘乌兰乌拉湖地区白垩纪地层剖面，将区内白垩系划分为错居日组和桑恰山组。沉积相分析表明，乌兰乌拉湖地区错居日组主要为冲积扇至河流相沉积，岩性及厚度变化较大，而桑恰山组为湖泊、湖三角洲至河流相沉积。初步认为错居日组为早日垩世地层，桑恰山组为早白垩世晚期至晚白垩世地层。     

冀西北尚义盆地中生代沉积特征及古地理*

尚义盆地形成于早侏罗世-早白垩世,盆地内沉积了一套以紫红色、灰绿色陆源碎屑岩为主的地层,仅在晚侏罗世-早白垩世地层局部夹薄层玄武安山质火山岩。通过系统分析尚义盆地的沉积岩、沉积相带展布特征及古水流、砾石成分等,分析了早侏罗世-早白垩世盆地的物源区、汇水中心及古气候的演化,恢复了早侏罗世-早白垩世盆地古地理格局。同时,在前人研究基础上,结合尚义盆地的沉积-充填样式,重点总结和综合分析了盆地内熔积岩、辉绿岩、边界断层等的发育特征,初步推断晚侏罗世-早白垩世尚义盆地为伸展断陷盆地。     

川西前陆盆地上三叠统沉积特征

应用层序地层学方法将川西前陆盆地上三叠统划分为4个三级层序和12个体系域。在层序格架内，研究了不同时期的古地理背景、物源、沉积类型和沉积相展布，明确了上三叠统存在龙门山古陆、米仓山-大巴山古陆、康滇古陆、江南古陆4个物源，识别出上三叠统海湾、冲积扇、曲流河、辫状河、扇三角洲、辫状河三角洲、曲流河三角洲和湖泊8种沉积相类型。层序Ⅰ沉积时期，盆地处于海陆交互相向陆相转变的时期，整体具有填平补齐的沉积特征，发育海湾等沉积；层序Ⅱ沉积时期，川西前陆盆地成为统一的内陆湖盆，其湖侵期为须家河期最大的湖侵期，主要发育三角洲沉积和湖相沉积；层序Ⅲ沉积时期，米仓山-大巴山古陆提供充足的物源，在米仓山-大巴山两逆冲推覆带前缘广泛发育大型冲积扇、辫状河、辫状河三角洲沉积体系；层序Ⅳ沉积时期，主要受江南古陆的影响，发育三角洲沉积和湖泊沉积。整体上，川西前陆盆地沉积相带的展布格局受构造控制，具有平行构造带展布的特点。盆地西北部陡坡带发育粗粒的冲积扇、扇三角洲-湖底扇，西南部陡坡带发育辫状河三角洲、北部-东北部陡坡带发育辫状河三角洲，而在东南部缓坡带则发育远源的曲流河、曲流河三角洲。     

燕山构造带滦平早白垩世盆地沉积过程和演化

滦平盆地是燕山构造带内一个具有代表性的早白垩世伸展盆地。对盆地内沉积岩相和相组合的详细分析结果显示,盆地内部发育不同的沉积相带并显示明显的空间变化。盆地北部和西部边缘以冲积扇砾岩和扇三角洲砂岩、砾岩沉积为主,盆地中心为湖泊细粒沉积。河流相砂岩和砾岩主要分布于盆地的东南部。古流向和物源恢复结果证明,盆地沉积物主体来自于北部和西部老变质岩基底,仅少部分沉积物来自盆地的东南缘。盆地构造沉降和沉积充填过程主要受北缘和西缘张性断层的控制,断层下盘基底岩石的抬升与盆地边界正断层活动相关,从而成为盆地主要的物源区。滦平盆地的演化可划分为三个阶段:即早期火山喷发阶段、中期强烈断陷阶段和晚期填平阶段。滦平盆地代表了早白垩世燕山构造带其它同类盆地的发展过程,它们皆以小型独立的盆地发育为特征。     

黑龙江北部孙吴——嘉荫盆地沉积相类型及其演化

通过对孙吴-嘉荫盆地淘淇河组、永安村组、太平林场组、鱼亮子组、乌云组和孙吴组露头剖面详细的沉积学研究,查明该盆地从淘淇河组到孙吴组发育的沉积相类型有冲积扇、辫状河、曲流河、扇三角洲、辫状河三角洲、曲流河三角洲、湖底扇和湖泊。冲积扇及扇三角洲主要发育于淘淇河组和孙吴组;辫状河及辫状河三角洲主要发育于鱼亮子组和乌云组;曲流河及曲流河三角洲主要发育于永安村组和太平林场组,各组均有湖泊相沉积发育。孙吴-嘉荫盆地从淘淇河组到乌云组,具有冲积扇-扇三角洲-湖泊→曲流河-曲流河三角洲-湖泊→辫状河-辫状河三角洲-湖泊→冲积扇-扇三角洲-湖泊的沉积演化规律,反映晚白垩-古新世构造活动性减弱,中-上新世孙吴组沉积时重又趋于活动。     

澳大利亚北波拿巴盆地东北部侏罗纪古地貌及沉积相特征

利用二维地震和钻井、测井资料探讨了北波拿巴盆地东北部侏罗纪各时期的古地貌和沉积相特征。整个侏罗纪时期,研究区整体处于裂陷作用的构造环境,发育由陆相至海相的5个三级层序。早侏罗世早期的古地貌主要受控于北西向构造格局,沉积中心主要是北西走向的凹陷和向斜。早侏罗世晚期开始,北东向构造开始发育,同时盆地整体剧烈沉降,北西和北东走向的构造单元发生切割和冲突,导致其内部的构造分区十分零碎。中侏罗世末期盆地北部发生大面积抬升形成Callovian不整合,之后的构造活动比较稳定,同时北东向构造基本形成,研究区进入缓慢拗陷时期。在此构造演化背景下,北波拿巴盆地东北部在早—中侏罗世主要是陆相的河流相和冲积扇沉积,中侏罗世主要是海陆过渡相的扇三角洲和三角洲沉积,而晚侏罗世则主要是浅海和滨岸沉积。     

川西前陆盆地中侏罗统沙溪庙组沉积相及平面展布特征研究

川西前陆盆地中侏罗统沙溪庙组具有巨大的勘探开发潜力,但对研究区沉积相研究成果却相对较少。本文根据岩性组合,岩石颜色,沉积构造等多种因素将研究区沙溪庙组划分出冲积扇、河流、扇三角洲、三角洲和湖泊五个沉积相,并对各沉积亚相构成特征进行了详细的研究。沉积相平面展布特征为物源主要来自于盆地西北部的龙门山,自西北向东南依次为冲积扇相-河流相-三角洲相-扇三角洲相-湖泊相。相的垂向序列反映湖泊具收缩-扩张-再收缩-再扩张的演变过程。     

合肥盆地圆筒山组物源分析及其地质意义：来自碎屑锆石的证据

合肥盆地位于华北板块东南缘,形成于华南、华北板块碰撞过程中。合肥盆地形成时表现为大别造山带向北逆冲形成的前陆挠曲盆地,早白垩世在区域伸展背景下转变为断陷盆地。中侏罗统圆筒山组是合肥盆地前陆挠曲阶段的沉积地层之一,主要表现为湖泊相沉积,与下伏的防虎山组典型的河流相沉积明显不同。为了获得圆筒山组更详细的物源信息,对肥西地区出露的圆筒山组紫红色粉砂岩开展了碎屑锆石LA-ICP MS U-Pb定年。定年结果显示,两个粉砂岩样品均获得了约2.0 Ga和约770 Ma两个主要峰值以及约2.4 Ga次要峰值。该特征与扬子板块锆石年龄分布特征几乎完全一致,指示圆筒山组物源应来自扬子板块。考虑到盆地地层的物源不应来自其周边隆起区分水岭的另一侧,因而推测圆筒山组物源应来自张八岭隆起中侏罗世时地表出露岩石。在燕山运动A幕影响下,下扬子地区发生逆冲褶皱活动,张八岭隆起发生明显隆升,上部岩石被剥蚀殆尽,仅保留现今出露的新元古代张八岭群及肥东杂岩,被剥蚀的岩石搬运沉积于合肥盆地内,形成圆筒山组。     

伊犁盆地南缘西段中下侏罗统水西沟群沉积体系及其对铀成矿的控制作用

通过野外地质露头和钻孔岩心观察以及对大量钻孔岩心编录和测井解释资料的综合统计分析,笔者将伊犁盆地南缘西段中下侏罗统水西沟群划分出4个大的沉积体系:八道湾组(J1b)的冲积扇沉积体系、三工河组—西山窑组一段的辫状河三角洲沉积体系、西山窑组二段至三段的浅湖沼泽沉积体系和西山窑组四段至五段的曲流河三角洲沉积体系。文中详细讨论了伊犁盆地南缘西段水西沟群各沉积体系的沉积相特征,研究了水西沟群沉积体系及沉积相与砂岩型铀矿的成矿关系,指出辫状河三角洲沉积体系是砂岩型铀矿成矿最有利的沉积体系,三角洲前缘河口坝及席状砂亚相、三角洲平原辫状河流亚相、扇中-扇端亚相及三角洲平原分流河道亚相是砂岩型铀矿主要的控矿沉积相。     

塔里木盆地塔北地区侏罗系沉积特征及演化

通过岩心观察与测井相分析,结合地震反射资料,认为塔里木盆地塔北地区侏罗系为冲积扇、辫 状河、三角洲与湖泊沉积体系。下侏罗统阳霞组主要发育冲积扇和辫状河沉积。其中冲积扇主要发育于盆地的 边缘,即研究区西部的英买力、北部的轮台及其西侧、东部的库南地区。冲积扇岩性主要为灰白、灰绿、灰褐 和紫红色块状砾岩、砾状砂岩及含砾砂岩,砾石成分复杂,分选差,磨圆程度低。多个冲积扇向盆地内演化为 辫状河沉积,发育各种交错层理与平行层理,其岩性为灰色、灰白色粗砂岩及含砾粗砂岩、细砾岩,垂向上具 有非常典型的下粗上细的 “ 二元结构” ,自然电位和自然伽马曲线具有明显的箱形特征,辫状河主体自西向东发 育。到阳霞组沉积晚期,在草湖地区演化为薄层细砂岩与泥岩互层的湖泊和含煤湖沼沉积;中侏罗统克孜勒努 尔组为三角洲沉积;上侏罗统普遍被剥蚀。早-中侏罗世盆地经历了水体由浅到深的沉积演化。