Evolution of Tectonic Uplift, Hydrocarbon Migration, and Uranium Mineralization in the NW Junggar Basin： An Apatite Fission-Track Thermochronology Study

The Mesozoic–Cenozoic tectonic movement largely controls the northwest region of the Junggar Basin（NWJB）, which is a significant area for the exploration of petroleum and sandstone-type uranium deposits in China. This work collected six samples from this sedimentary basin and surrounding mountains to conduct apatite fission track（AFT） dating, and utilized the dating results for thermochronological modeling to reconstruct the uplift history of the NWJB and its response to hydrocarbon migration and uranium mineralization. The results indicate that a single continuous uplift event has occurred since the Early Cretaceous, showing spatiotemporal variation in the uplift and exhumation patterns throughout the NWJB. Uplift and exhumation initiated in the northwest and then proceeded to the southeast, suggesting that the fault system induced a post spread-thrust nappe into the basin during the Late Yanshanian. Modeling results indicate that the NWJB mountains have undergone three distinct stages of rapid cooling： Early Cretaceous（ca. 140–115 Ma）, Late Cretaceous（ca. 80–60 Ma）, and Miocene–present（since ca. 20 Ma）. These three stages regionally correspond to the LhasaEurasian collision during the Late Jurassic–Early Cretaceous（ca. 140–125 Ma）, the Lhasa-Gandise collision during the Late Cretaceous（ca. 80–70 Ma）, and a remote response to the India-Asian collision since ca. 55 Ma, respectively. These tectonic events also resulted in several regional unconformities between the J3/K1, K2/E, and E/N, and three large-scale hydrocarbon injection events in the Piedmont Thrust Belt（PTB）. Particularly, the hydrocarbon charge event during the Early Cretaceous resulted in the initial inundation and protection of paleo-uranium ore bodies that were formed during the Middle–Late Jurassic. The uplift and denudation of the PTB was extremely slow from 40 Ma onward due to a slight influence from the Himalayan orogeny. However, the uplift of the PTB was faster after the Miocene, which led to re-uplift and exposure at the surface during the Quaternary, resulting in its oxidation and the formation of small uranium ore bodies.

Structural Evolution of Chepaizi Uplift and its Control on Stratigraphic Deposition in the Western Junggar Basin, China

Geological mapping,interpreted cross sections,structural analyses and residual thickness maps were used to characterize the evolution of stress setting,structure and stratigraphic distribution of the Chepaizi Uplift,which is a NW-SE trending structure located in the Western Junggar Basin.The NS-trending faults show an important transpressional phase during the Late Permian,as demonstrated by tectonic stress field and stratigraphic thickness variations.A major compressional thrusting and strike-slip phase during the Late Jurassic created a series of NW-SE faults that originated by the large-scale uplift event in the Northern Tianshan.Faults were reactivated as thrust and dextral strike-slip faults.In addition,the angular unconformity observed between Jurassic and Cretaceous provide evidence of this tectonic event.Lots of normal faults indicate that the area records southward tilting and regional derived extensional stress that took place during the Neogene.Before that,thick Early Cenozoic strata are widely deposited.The balanced cross-section highlights the evolution of stress setting and stratigraphic distribution of the Chepaizi Uplift.

East central Uplift Belt of Junggar Basin

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Fault characteristics and control on hydrocarbon accumulation of middle-shallow layers in the slope zone of Mahu sag, Junggar Basin, NW China

The development, evolution and formation mechanism of faults and their control on the migration and accumulation of Mesozoic oil and gas in the middle-shallow layers of the slope zone of Mahu sag were studied by the interpretation of seismic and drilling data. Two types of faults, normal and strike-slip, are developed in the middle-shallow layers of the slope zone of the Mahu sag and they are mostly active in the Yanshanian period. They are divided into four grade faults: The grade I strike-slip faults with NWW to near EW direction are related to the left-lateral transpressive fault zones in the northwest of Junggar Basin since the end of the Triassic. The grade II faults with NE to NNE direction are the normal faults located at the junction of the fault zone and the slope zone, and their formation is related to the extension at the top of the nose-like structures in the fault zone. The grade III faults, which are also the normal faults, are the result of the extension at the top of the lower uplifts in the slope zone and differential compaction. The grade IV faults with NE direction are normal faults, which may be related to the extension environment at the tip of the lower uplifts. Faults not only are the channel for the vertical migration of oil and gas, but also control the oil-gas accumulation. There are two types of oil-gas reservoirs in the middle-shallow layers of slope zone of Mahu sag: fault block reservoirs and fault-lithologic reservoirs. They have large traps and promising exploration potential.

新疆准噶尔盆地白家海凸起深部煤层气勘探开发进展及启示

白家海凸起侏罗系煤是国内深部煤层气直井产量很早取得突破的地方,为准噶尔盆地的重要靶区。煤储层为特低灰、低水分、中高挥发性煤,孔渗系统较好。具有“古生新储”和“自生自储”两种成藏模式,煤层含气量高、游离气占比高、含气饱和度高,为优质煤层气储层。历经多年的勘探开发证明:多数直井试采无需排水降压即可快速见气(2~5 d),排采初期日产气量较高(2100~9890 m^(3)),日产水量少甚至不产水(<5 m^(3)),可自喷生产,返排率低,长期试采压力均衡下降,且具有一定的稳产期(25~60 d);煤层射孔层厚度、压裂液体系、压裂加砂比均可影响煤层气试气效果,其中冻胶、胍胶体系优于活性水-清洁压裂液体系。最新施工的彩探1H水平井试采表现出压裂开井后即高产,试采最高日产气量5.7万m^(3),日产水量少(0.5~3.0 m^(3)),表现出常规天然气特征,随后衰减稳定,表现为吸附气与游离气共同产出;与直井对比,水平井产量高、稳产时间长、压降速率小。基于研究区储层特征和含气性特征,及勘探开发历程,得到3方面启示。一是深部多类型气藏富集规律再认识:需重视油气运聚圈闭的成藏演化研究,重视深部位气水空间分配和富集规律的研究。二是深部中低阶煤储层可压性评价:针对凸起高部位孔渗系统好的中低煤阶储层,需形成适合的压裂工艺体系。三是深部多类型气藏开发方式优化:针对游离气占比高的气藏,实现游离气-吸附气的接续产出,保持降压面积稳定扩展,排采控制尤为关键。

新疆准噶尔盆地白家海凸起深部煤层气孔渗系统特征

【目的】新疆深部煤层气资源丰富,其中准噶尔盆地白家海凸起侏罗系煤层是深部煤层气勘探开发的有利目标区。深部煤层气孔渗系统直接决定了深部煤层气的可采性。【方法】以新疆油田2023年最新施工的彩煤2-004H评价井为基础,基于扫描电镜观察,压汞–低温液氮–二氧化碳吸附、低场核磁共振、CT扫描,变温压孔渗实验,结合数学建模,深入研究了本区侏罗系西山窑组煤的孔渗系统。【结果和结论】结果表明:(1)研究区深部煤储层孔隙类型以植物组织孔和气孔为主,孔裂隙发育,形态多为板状和狭缝状,孔裂隙连通性好,多为开放型孔。(2)全孔径表征结果显示,超微孔最为发育,其次为中孔和过渡孔,各类型孔隙发育较为均匀,总孔比表面积和总孔容较大,接近于贫煤和无烟煤,暗示了其吸附性和储集能力较强,其主要地质原因在于其煤层为特低灰分(平均灰分在5%左右)煤、煤岩显微组分中主要为丝质体和结构腐殖体,且处于构造高部位的煤储层断裂发育。(3)考虑温度和有效应力对孔隙率和渗透率的影响,建立了研究区孔隙率和渗透率与埋深的关系式。与鄂尔多斯盆地大宁-吉县区块深部煤相比,不论是常规孔渗结果,还是模拟原位储层条件下的孔渗系统,白家海凸起深部煤储层孔隙率和渗透率均较大,原位储层条件下孔隙率介于8.60%~10.21%,渗透率介于(0.04~0.21)×10^(-3)μm^(2)。即本区深部煤储层孔渗系统,不仅储气能力较强,同时其导流能力也较好。

准噶尔盆地中拐凸起东斜坡上乌尔禾组常规—致密油藏主控因素及成藏模式

准噶尔盆地中拐凸起东斜坡上乌尔禾组油气资源丰富,是效益勘探及建产的重要领域。应用测录井、生产测试及岩心分析化验资料,研究中拐凸起东斜坡上乌尔禾组储层特征,明确储层差异性的主控因素,建立中拐凸起东斜坡常规—致密油藏序次分布的成藏模式。结果表明:自北部向南部,研究区逐步由常规油藏转化为致密油藏,沉积作用是造成储层差异性的物质基础,控制储层岩性及原始物性,压实作用和浊沸石胶结作用加剧储层常规—致密差异演化;研究区成岩相带划分为泥质充填带、贫泥—弱胶结带、浊沸石胶结带和强压实—弱溶蚀带4种相带,其中贫泥—弱胶结带为有利储层发育带。该结果为研究区致密油藏勘探提供指导。

准噶尔盆地车排子凸起中生界稠油油源分析

为明确准噶尔盆地车排子凸起中生界稠油的油源,利用中生界原油的气相色谱-质谱分析结果,结合层次聚类分析法、生物标志物参数恢复法,对原油生物降解程度进行定量评价,对典型生物标志物原始质量进行恢复,并对严重生物降解的稠油进行油源研究。结果表明:车排子凸起中生界原油生物降解级别达到6级以上(PM6),可细分为A1、A2两个族群。所提出的生物标志物参数恢复法进行油源对比效果显著,证实了A1原油与沙湾凹陷二叠系烃源岩具有亲缘性,A2原油可能来自沙湾凹陷二叠系烃源岩、车排子凸起石炭系烃源岩及四棵树凹陷侏罗系烃源岩的混合,主成分分析(PCA)进一步支持和验证了该结论。研究结果对深化车排子凸起中生界的油气勘探部署具有重要参考作用。

低程度风化火山岩风化壳结构划分与主控因素——以准噶尔盆地西缘车排子凸起石炭系火山岩为例

为解决低风化程度的火山岩风化壳结构划分及火山岩油气储层评价与预测的难题,利用研究区28口井岩心、录井测井和地震资料,对车排子凸起石炭系火山岩风化壳的岩石学、矿物学、地球化学、储层物性进行系统研究。结果表明:研究区岩石整体风化程度偏低。在此基础上提出一种将风化壳自上而下分为土壤带、水解带、淋滤带、崩解带、蚀变带、母岩带的6层划分方案。利用研究区玄武安山岩的自然电位、自然伽马、声波、电阻率4种测井数据,结合过采样算法的决策树模型对淋滤带、崩解带、蚀变带进行分类判别,准确率达87.8%。综合分析认为:低风化程度火山岩风化壳有效储层厚度、结构带发育程度、横纵向分布等具有非均质性;有利储层发育主要受古地貌和断裂作用的控制,淋滤带、崩解带是主要有利储层发育区,常分布于古地貌的斜坡地带,一般厚度在350 m以内;受断裂作用影响,风化壳有效储层厚度可达450 m。

The formation and evolution of Chepaizi-Mosuowan paleo-uplift and its control on the distributions of sedimentary facies in the Junggar Basin

The Chepaizi-Mosuowan paleo-uplift is a large-scale uplift stretching across the Junggar Basin formed during the Yanshanian. It has experienced four evolutionary stages: the initial forming stage (J1), the intense development stage (J2+3), the waning and burial stage (K-E), and the tilting and extinction stage (N-Q). The most intense period of activities is the Middle Jurassic. Dur-ing the Early Jurassic, the Chepaizi-Mosuowan paleo-structure was a low amplitude uplift. Because of the subsequent strong uplifting during Middle-Late Jurassic, the Middle and Upper Jurassic were eroded. With the evolution of the Chepaizi-Mosuowan paleo-uplift, the sedimentary pattern of the basin changed, and the paleo-uplift separated the northern depositional systems from those in the south side. As a result, the basin tectonics controlled the distribution and evolution of the depositional systems. During Early Jurassic, while the paleo-uplift was low, its controlling effect on depositional systems was limited and sediments coming from the northwest could reach the central and southern parts of the basin. With the strong uplifting of the Chepaizi-Mosuowan paleo-structure during Middle-Late Jurassic, sediments from the northwest provenance could only deposit in the northern graben of the paleo-uplift. The intense erosion of the Middle-Upper Jurassic also changed the former sedimentary center of the basin into a source area, supplying sediments for grabens on both sides of the paleo-uplift. In the Cretaceous, regional subsidence caused the paleo-uplift to be buried again and subsequently sediments accumulated on top of it. The depositional facies are dominated by fluvial in the Early Cretaceous and shallow lacustrine to deltaic in the Late Cretaceous. In the history of the long-lasting development of this paleo-uplift, large-scale erosions of the paleohigh not only provided sufficient sediments to the center of the Junggar Basin, but also created favorable conditions for the formation of various subtle traps such as lithologic and stratigraphic traps.

准噶尔盆地西北缘车排子凸起原油类型与油源

准噶尔盆地西北缘南部红车断裂带-车排子凸起油气藏众多,原油物理化学性质和地球化学特征十分复杂,原油类型及其来源长期存在很大争议。本文在准噶尔盆地不同时代烃源岩生成原油典型地球化学特征与主要油源判识指标归纳总结的基础上,对红车断裂带-车排子凸起原油地球化学特征和来源进行系统分析研究,将该区域原油分为五类,其中三类原油分别来源于二叠系湖相烃源岩、中—下侏罗统煤系烃源岩、古近系安集海河组湖相烃源岩,另外两类为混合原油,分别为来源于二叠系湖相烃源岩的生物降解稠油与中—下侏罗统煤系烃源岩生成的正常原油和古近系湖相烃源岩生成的正常原油的混合原油。红车断裂带石炭系—白垩系油藏原油主要来源于沙湾凹陷二叠系湖相烃源岩,车排子凸起东北部春风油田稠油来源于沙湾凹陷二叠系湖相烃源岩;车排子凸起东侧-红车断裂带西侧新近系沙湾组油藏轻质原油来源于四棵树凹陷古近系湖相烃源岩;车排子凸起中部春光油田白垩系—古近系油藏稠油为二叠系来源稠油和侏罗系正常原油的混合原油,新近系沙湾组油藏稠油为二叠系来源稠油与新近系正常原油的混合原油;车排子凸起西部石炭系—古近系油藏轻质原油来源于四棵树凹陷中—下侏罗统煤系烃源岩,而新近系沙湾组油藏轻质原油来源于四棵树凹陷古近系湖相烃源岩。本文对准噶尔盆地西北缘南部地区油气藏成藏研究及区域油气勘探决策具有重要参考作用。

准噶尔盆地东北缘上三叠统烃源岩地球化学特征与油源对比

准噶尔盆地东北缘陆梁隆起北部至乌伦古坳陷上三叠统白碱滩组分布广泛,厚度大,烃源岩发育,烃源岩主要沿乌伦古坳陷索索泉凹陷伦参1—乌伦1—乌参1井和准北1—泉1—滴北1井一带分布。根据钻井资料,分析研究区烃源岩及油砂样品总有机碳质量分数、生烃潜量、镜质体反射率、干酪根碳同位素、饱和烃色谱、饱和烃色质和芳烃色质等,利用生物标志物进行烃源岩和油源对比。结果表明:乌参1和滴北1井上三叠统白碱滩组烃源岩丰度基本为中等—好,有机质类型主要为Ⅱ_(2)型,部分为Ⅱ_(1)和Ⅲ型;凹陷区烃源岩处于低成熟—成熟阶段,具有较好的生油气潜力。白碱滩组烃源岩与滴北1井八道湾组油砂抽提物生物标志物Pr/Ph约为1.4,几乎不含伽马蜡烷和β-胡萝卜烷,Ts相对于Tm很低,C_(27)、C_(28)、C_(29)规则甾烷相对含量组成中,C_(29)规则甾烷含量最高,C_(27)和C_(28)规则甾烷含量较低,呈反“L”型分布。滴北1井侏罗系八道湾组油砂抽提物生物标志物与上三叠统白碱滩组烃源岩具有良好的亲缘关系,八道湾组原油来源于白碱滩组烃源岩。石英滩凸起东南部—滴北凸起上三叠统—侏罗系为勘探有利区。该结果为上三叠统烃源岩生烃模拟、资源量评价及勘探部署提供依据。

准噶尔盆地东部构造抬升剥蚀对铀成矿的控制

构造与成矿具有密切的动态耦合关系,长期研究发现目标层形成和之后的构造抬升剥蚀事件对砂岩型铀矿的形成和定位具有明显控制作用。为了详细地、较为合理地刻画不同类型、不同层位铀矿形成的机理和过程,实现理论模式向找矿模型的转化,建立一种可便于操作的远景预测新方法和新途径,以准噶尔盆地东部卡拉麦里山周缘铀矿床(点)为研究对象,采用盆地构造格架划分、埋藏与剥蚀史研究和蚀源区磷灰石裂变径迹模拟的方法,开展了系列研究工作。研究发现卡拉麦里山周缘不同类型的铀矿床(点)是其抬升剥蚀演化这同一成矿系统作用下的不同产物。盆地沉降曲线和蚀源区磷灰石裂变径迹模拟显示准噶尔盆地东部在中晚侏罗世以来经历了160~140、90~70和约20 Ma以来的3次快速隆升剥蚀阶段,这些构造事件均诱发了明显的铀成矿作用,其构造抬升剥蚀的强度控制了铀成矿的规模,其期次严格地控制了铀成矿的期次。在铀成矿过程中构造发展演化起到了主导作用,规模铀成矿主要发育在有完整成矿系统的构造斜坡带上,如喀木斯特进积式(剥蚀)多期次同向叠加和北三台退积式远源铀成矿模式往往能形成大型矿床;构造形态复杂多变的区段一般不会发育规模铀成矿,如卡拉麦里山南缘山前地区。上述区域构造抬升、铀成矿序列和控矿组合等规律的总结,为该区铀成矿远景预测提供了科学依据,可推广应用到其他盆地砂岩型铀矿找矿当中。

准噶尔盆地石英滩凸起正反转构造及成因机制

构造反转是沉积盆地构造演化的关键基础过程之一,其形成演化受到多因素的控制,对研究油气圈闭的形成具有重要价值。陆梁隆起是准噶尔地区石炭纪多岛弧构造体系的重要组成之一,石炭纪裂陷背景下发育的断陷结构在二叠纪以来经历了多期次构造作用的叠加和改造。本文针对陆梁隆起北部石英滩凸起开展精细构造建模,依据不整合面、生长地层约束构造演化时空格架,正演、反演相结合建立构造演化模式。研究结果表明:1)石英滩凸起反转构造受控于3条主要断裂,石西断裂(Fsx)、石英滩南断裂(Fssyt)、石英滩北断裂(Fnsyt),控制石西凹陷—石英滩凸起石炭系非对称地堑结构。2)石英滩凸起及邻区构造演化历经早石炭世断陷伸展期,早-晚石炭世之间弱断陷—坳陷过渡期,晚石炭世伸展—挤压转换期,早二叠世弱伸展期,中二叠世—中三叠世挤压以及中、晚侏罗世—早白垩世挤压6期重要构造事件,其中反转构造活跃于晚石炭世末期和中-晚侏罗世—早白垩世。3)正、反演结果表明石西断裂(Fsx)、石英滩南断裂(Fssyt)控制石炭纪断陷结构,后期的改造作用主要激活了石英滩南断裂(Fssyt),断陷的发育与反转构造可能受控于多期次构造变形中最大构造主应力的优势方向转变。

准噶尔盆地东部隆起石钱滩凹陷石钱滩组层序划分

为建立石钱滩凹陷上石炭统石钱滩组标准剖面,给凹陷内井下地层划分对比及油气勘探提供依据,以野外调查为重点,利用地质探槽,根据岩性特征、沉积建造、接触关系、标志层、生物化石等综合分析,进行石钱滩组层序划分和沉积相恢复及区域地层对比。石钱滩组由洪积扇(扇三角洲)沉积开始,经扇前湖泊沉积,于海湾潟湖沉积结束,构成3次海侵退积型层序,可划分为3段。下段下部为砾岩和砂砾岩,夹砂岩和粉砂岩,中部为中—细砾岩、杂砂岩与泥岩和粉砂质泥岩互层,上部为粉砂质泥岩、泥岩夹砂岩和粉砂岩;中段下部为砾岩、含砾砂岩和砂岩,夹粉砂岩,上部为钙质粉砂质泥岩、泥岩、粉砂岩和泥质灰岩;上段下部为砾岩、砂岩与粉砂岩和粉砂质泥岩互层,中部为紫褐色、砖红色泥岩和泥质粉砂岩,夹含砾粗砂岩和砾岩,上部为深灰色泥岩和粉砂质泥岩夹灰岩。宏观上为下段、中段及上段上部为深灰色,上段下部为浅褐—砖红色,各段均为正粒序。扇前沼泽—海湾潟湖相暗色泥岩为有利烃源岩,扇中、扇端砂岩和砾岩为储集层,生储配置好,油气地质条件优越。

准噶尔盆地夏盐凸起二叠系油气成藏期次与成藏过程

通过流体包裹体透射光和荧光镜下观察、包裹体测温及储层定量荧光测试,对夏盐凸起二叠系碎屑岩储层流体包裹体特征、油气成藏期次及油气类型进行了研究.结果表明:夏盐凸起二叠系碎屑岩储层流体包裹体较为发育,主要在石英颗粒微裂隙和方解石胶结物中呈带状分布,烃类包裹体荧光呈黄绿色—蓝色,说明研究区存在不同成熟度的原油;包裹体盐度呈明显的双众数特征,表明研究区在地史时期至少经历过两期流体活动;由包裹体均一温度测试结果与埋藏史和热演化史,认为研究区二叠系碎屑岩储层主要经历了两期油气充注,分别为三叠纪末期和白垩纪早中期,结合储层定量荧光测试结果可知,第一期充注以中质油为主,第二期充注以轻质油为主.

准噶尔盆地车排子-莫索湾古隆起的形成演化与成因机制

准噶尔地块是在前寒武纪"微"地块与环绕它的早古生代陆缘增生褶皱带的基础上经历石炭—二叠纪过渡阶段的构造演化之后固结形成的新克拉通地块。准噶尔盆地是在这一"新克拉通"之上发展起来的克拉通内坳陷盆地(T—E)与前陆盆地(N—Q)相叠加而成的叠合沉积盆地。周缘边界断裂带的多期活动与基底的非均一性使该"新克拉通地块"在后期活动强烈,集中表现在准噶尔盆地腹部于中—晚侏罗世形成了一个大型的SWW-NEE向的车排子-莫索湾隆起。该隆起经历了燕山早期(J1s)初始发育、燕山中期(J2x,J2t)强烈发育并定型、燕山晚期埋藏隐伏和喜马拉雅期掀斜消亡的完整过程。它是在中—晚侏罗世区域压扭背景之下,受周缘边界断裂带活动的控制,侏罗—白垩系构造层和石炭—三叠系构造层上下拆耦,发生镜像旋转而形成的压扭性构造带,为一形态不规则的复合性质隆起。车排子-莫索湾隆起对沉积与油气成藏有明显的制约作用,其两翼发育了一系列岩性、地层圈闭,目前发现了石南21、石南31、莫北、莫西庄和永丰等多个大中型油气田。车排子-莫索湾隆起将是准噶尔盆地腹部下一步岩性、地层油气藏勘探的重要领域。

准噶尔盆地车莫古隆起构造特征与成藏模式

准噶尔盆地车莫古隆起为南西—北东走向的燕山期古隆起,分布范围大于2×104km2。现今车莫古隆起的深层仍存在低幅度的背斜构造和鼻状构造,浅层构造简单、断裂不发育。其形成演化可划分为5个阶段,即:凸起形成阶段、缓慢发育阶段、强烈发育阶段、隐伏埋藏阶段和改造调整阶段。车莫古隆起提供了形成各种地层、岩性等隐蔽型圈闭的条件和良好的油气运聚背景,有利于盆地腹部大范围、区域性的油气成藏。

准噶尔盆地腹部侏罗系顶部红层成岩作用过程中蕴藏的车莫古隆起演化信息

准噶尔盆地腹部车莫古隆起演化过程研究直接关系到油气勘探部署,最新通过对K/J不整合界面之下红层的研究发现成岩作用可以为车莫古隆起演化历史提供一些可靠信息.研究认为红层系赤铁矿化所致,非同沉积期的产物,其形成机理类似于砂岩型铀矿形成过程中的潜水氧化和层间氧化作用模式.研究区的红层曾经历了初始压实作用、淋滤作用(赤铁矿化,或称褐色蚀变,导致红层形成)、白云石化钙质胶结作用、硅质胶结作用、方解石化钙质胶结作用、再次压实作用(压裂)和绿泥石化胶结作用的演化过程.成岩作用的有序演化记录了车莫古隆起的演化历史,初始压实作用预示着侏罗系连续沉积并一度被深埋,车莫古隆起隆升速率小于盆地沉降速率;随之而来的褐色蚀变预示着车莫古隆起大幅度抬升,侏罗系被剥蚀出露地表并遭受了全面的潜水氧化和层间氧化作用;再次压实作用和大规模胶结作用预示着侏罗系被再次深埋,这是准噶尔盆地白垩系和新生界充填的结果.由此可见,成岩作用蕴藏了丰富的盆地构造演化历史信息,成岩作用是盆地构造作用的响应.

准噶尔盆地古隆起的分布与基本特征

准噶尔盆地外侧三大边界动力体系的作用及基底结构的差异性导致准噶尔盆地在不同地质时期发育不同性质的隆起构造。石炭纪晚期东北侧的造山作用形成了盆地北部隆起,晚二叠世北部隆起分异为陆梁隆起与乌伦古坳陷;早二叠世西北侧的造山作用形成了车排子隆起,随后的冲断作用形成了克拉玛依—夏子街断裂带。燕山期的压扭作用形成了沉积盖层中的车排子—莫索湾隆起。新生代北天山向北的冲断作用导致准噶尔盆地南部地区急剧挠曲沉降,盆地向南掀斜,隆起向北迁移。据基底的性质、形成时间、活动方式、地质结构与保存状态等特点将准噶尔盆地的隆起划分为继承型、间断型、掀斜型与冲断带型等4种基本类型。