Authigenic clay minerals and calcite dissolution influence reservoir quality in tight sandstones:Insights from the central Junggar Basin,NW China

Authigenic clays and calcite cements are important in the development of reservoir tightness and the formation of hydrocarbon sweet spots.We investigated Jurassic low-permeability sandstone reservoirs in the central Junggar Basin,NW China,using petrography,mineralogy,porosity,and permeability assessment,and stable C and O isotope analysis to ascertain the influence of authigenic clays and calcites on reservoir quality.Here,we establish the properties and diagenetic processes of the reservoir sandstones,and construct a generalizable model of reservoir quality.The results show that the sandstones are mainly litharenite and feldspathic litharenite and can be classified into ductile-lithic-rich sandstones and ductile-lithic-poor sandstones according to rock composition.The ductile-lithic-rich sandstones are tight(mean porosity?7.31%;mean permeability?0.08 mD)as a result of intense compaction.In contrast,the ductile-lithic-poor sandstones can be classified into five types according to diagenetic process.The formation of favorable hydrocarbon reservoir properties is closely related to the presence of authigenic clays and dissolution of calcite.In particular,kaolinite fills intergranular pores,thereby blocking pore space and reducing reservoir quality.Chlorite coating resists compaction and limits the formation of quartz overgrowths,thereby preserving pore space and enhancing reservoir quality.Calcite controls reservoir quality through both precipitation and dissolution.Calcite precipitation results in reduced reservoir quality,whereby early calcites that were precipitated in formation water resist compaction and provide the basis for subsequent dissolution and late precipitation,whereas dissolution of calcite in mesodiagenesis improves reservoir quality.A generalized model is formulated by relating diagenetic facies types to depth and porosity,providing a reference for other similar reservoirs.Our data suggest that deeply buried tight sandstones can be exploration prospects under favorable conditions involving the presence of authigenic clays and dissolution of calcite,as in the central Junggar Basin of this study.

High-Resolution Sequence Stratigraphy of Shallow Lacustrine Delta Front: The Second Member of Sangonghe Formation, Central Junggar Basin

Shallow lacustrine delta front （SLDF） comprises mainly sheetlike subaqueous distributary channels （SDC） formed in shallow, gentle, and tectonically steady slope （Cai and Zhu, 2011）. SDC proves an important hydrocarbon reservoir type in the Daqing oilfield, Changqing oilfield, and the newly discovered Moxizhuang oilfield in Central Junggar Basin. However, SDC tends to prograde quickly and move laterally frequently,

Carbonate cementation-dissolution in deep-seated sandstones near the overpressure top in central Junggar Basin, Xinjiang, NW China

Fluid/rock interaction occurs frequently in the sandstones near the overpressure top in central Junggar Basin, and carbonate cementation-dissolution is related closely to the formation of secondary pores in the reservoir sandstones. From petrological, hydrochemical and fluid-inclusion studies of the deep-seated sandstones near the overpressure top in central Junggar Basin and the carbon and oxygen isotopic characteristics of carbonate cements in those sandstones, the following conclusions can be drawn: (1) Carbonates are the major cements. Two-stage cementation was commonly developed, with late-stage ferroan carbonate cementation being dominant; several secondary porosity zones were developed vertically in the sandstones near the overpressure top, and there is a mutually compensatory relationship between the carbonate contents and the mean porosity; (2) the alkalescent formation-water chemical environments are in favor of carbonate precipitation; (3) there were two phases of thermal fluid activity which are related to the late-stage carbonate cementation-dissolution; (4) with the overpressure top as the boundary, carbonate cements in the sandstones have slightly negative δ13C and δ18O values, showing such a variation trend that the δ13C and δ18O values near the coal-bearing Jurassic strata are lighter, those in the overpressure top are heavier, and those at the upper part of the overpressure top are lighter, which is considered to be the result of kinetic isotope fractionation driven by episodically overpressured fluid flow; (5) carbonate cementation is closely associated with the decarboxylation of organic acids, and secondary porosity zones resultant from dissolution by organic acids and CO2 derived from Jurassic coal-bearing strata, are the most important reservoir space of hydrocarbon, Studies of the mechanisms of carbonate cementation-dissolution and formation of secondary pores in the deep-seated sandstones near the overpressure top are of great significance both in theory and in practice in further investigating the rules of overpressured fluid flow (especially oil/gas migration) and predicting the reservoir space of hydrocarbon.

Formation mechanism of carbonate cemented zones adjacent to the top overpressured surface in the central Junggar Basin,NW China

Carbonate cemented zones are normally adjacent to the top overpressured surface in the central Junggar Basin,NW China.Stable carbon and oxygen isotopic compositions and petrological investigations of carbonate cements in the carbonate cemented zones indicate that:(1) carbonate cements are composed dominantly of ferrocalcite,ferroan dolomite,and ankerite;(2) carbonate cements are formed under a high temperature circumstance in the subsurface,and organic fluid migration has an important effect on the formation of them;and(3) carbon and oxygen ions in the carbonate cements migrate from the underlying overpressured system.This suggests that the occurrence of carbonate cemented zones in this region results from multiple phases of organic fluid expulsion out of the overpressure compartment through geological time.This study provides a plausible mechanism of the formation of carbonate cemented zones adjacent to the top overpressured surface in the clastic sedimentary basins,and has an important implication for understanding the internal correlation between the formation of carbonate cemented zones adjacent to top overpressured surface and geofluids expulsion out of overpressured system.

East central Uplift Belt of Junggar Basin

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准噶尔盆地中央坳陷西部下二叠统风城组天然气勘探潜力与重点领域

基于准噶尔盆地中央坳陷西部下二叠统风城组烃源岩有机地球化学、天然气组分和稳定碳同位素组成等分析数据,结合区域沉积环境与生烃演化模拟实验,评价风城组烃源岩的生气潜力,刻画规模有效源灶分布,厘定天然气成因来源,优选有利勘探领域。结果表明:(1)风城组为1套倾油型烃源岩,但滞留液态烃有利于晚期裂解成气,具有生气潜力大、晚期规模成藏的特点;(2)风城组烃源岩最大厚度可达900 m,盆1井西凹陷和沙湾凹陷已进入规模生气阶段,生气强度大于20×10^(8) m^(3)/km^(2)的面积约6 500 km^(2);(3)环中央坳陷西部发现的碳同位素组成较轻的天然气主要为来自风城组烃源岩的高熟油型气,其他则为来自于石炭系煤系烃源岩的煤成气;(4)中央坳陷西部天然气勘探需重点关注源边构造型、源边地层型、源内页岩气型和源内构造型4种类型的有利勘探领域,其勘探潜力值得期待。

新疆准噶尔盆地东缘中—晚二叠世植物群及其地质意义

本文首次报道了新疆准噶尔盆地东缘胜利沟中二叠世平地泉组植物化石11属19种和晚二叠世黄梁沟组植物化石7属9种,并结合前人对这一地区中—晚二叠世植物化石记录,讨论了两个植物群的地质时代。研究认为:中二叠世平地泉组植物群以安加拉植物群为主,混生个别欧美植物群分子;晚二叠世黄梁沟组植物群为混生少量华夏植物群分子的安加拉植物群。在此基础上,探讨了中—晚二叠世植物群演替、植被变化、植物群混生与中亚造山带板块聚合之间的关系,认为中二叠世的暖温带温湿气候在晚二叠世转变为季节性干热气候,准噶尔盆地东缘中—晚二叠世植物群混生与准噶尔—吐哈地块、塔里木板块、佳蒙地块、华北板块的拼合和古亚洲洋的关闭密切相关。

准噶尔盆地中部原油地球化学特征

准噶尔盆地中部1区块和3区块原油地球化学特征相近,正构烷烃分布完整,呈单峰型,主峰碳为C17～C23,弱姥鲛烷优势(Pr/Ph为1.33～1.75).生标特征:三环萜烷含量丰富,伽马蜡烷含量高,孕甾烷、升孕甾烷含量较高,规则甾烷呈'上升型'分布,ααα20RC27相对含量高,β - 胡萝卜烷和γ - 胡萝卜烷含量高.碳同位素值偏轻(一般小于 - 29‰),生源构成可能以低等水生生物和菌藻类为主,母源形成环境为湖相还原环境.原油主要源自二叠系源岩.中部2区块和4区块原油地球化学特征相近,正构烷烃分布完整,呈单峰型,主峰碳为C13和C19,明显姥鲛烷优势(Pr/Ph为5.62～7.24).生标特征:三环萜烷含量很低,伽马蜡烷含量较低或缺乏,孕甾烷、升孕甾烷含量低,C29甾烷含量很高,规则甾烷呈'反L型'分布,不含β - 胡萝卜烷和γ - 胡萝卜烷.碳同位素偏重(一般大于 - 27‰),生源构成可能以高等植物为主,母源形成环境为氧化环境.原油主要源自侏罗系煤系烃源岩.

准噶尔盆地腹部永进地区砂岩储层中碳酸盐胶结物特征及其成因意义

准噶尔盆地腹部永进地区不整合面附近砂岩储层中次生孔隙和碳酸盐胶结物相对发育。通过薄片观察、阴极发光、扫描电镜/能谱分析,认为碳酸盐胶结物是研究区砂岩最主要的胶结物成分,其主要类型为(铁)方解石和铁白云石,垂向上含量随深度增加而增加,多集中分布在白垩系和侏罗系之间的不整合面之下约100m的范围之内。碳、氧同位素分析以及泥岩中各元素测试结果表明,大气淡水通过永进地区白垩系和侏罗系之间存在的角度不整合对其下伏地层物性作用不明显,晚期含铁碳酸盐胶结物和孔隙发育主要与有机酸关系密切。在有机酸作用下,早期发育的碳酸盐胶结物、长石碎屑颗粒以及粘土矿物为晚期碳酸盐胶结物的发育提供了物质基础,而且溶解的物质在酸性流体作用下运移至不整合面附近重新沉淀,造成高孔隙度和高含量碳酸盐胶结物在深度上具有重叠的特征。由于含铁碳酸盐胶结物形成时代晚而且储层未受到其他建设性成岩作用的明显改造,晚期碳酸盐胶结物含量和面孔率呈互相补偿的关系,表明了晚期碳酸盐胶结物对储层物性的破坏作用。

准噶尔盆地腹部陆西地区二叠系-石炭系火山岩地球化学特征及构造背景分析

通过对准噶尔盆地腹部陆西地区基底二叠系佳木河组—石炭系107个火山岩样品的全岩元素分析表明,其中38.7%属钙碱性系列,碱性系和强碱性系列占61.3%。该区火山岩不仅在纵向上分异、演化特征明显,在平面上也存在明显的分区分带性。研究表明,陆西地区火山岩喷发的构造环境具有岛弧体系特征,同时由于火山岩的主量元素和微量元素均具有明显的大陆稳定构造区派生的碱性火山岩特征,说明其岩浆源深度较大,可能为上地幔或洋壳物质在高等选择性熔融条件下形成。因此盆地腹部陆西地区火山岩的喷发环境应该是在岛弧发展后期,属于岛弧近大陆一侧、在地壳增厚的环境下喷发。

准噶尔盆地腹部侏罗系原油勘探前景探讨

准噶尔盆地腹部地区长期以来以二叠系原油的勘探与研究为主。本文在总结本区现已发现侏罗系典型原油地球化学特征的基础上,通过混源油人工配比模拟实验揭示了侏罗系与二叠系原油在混合过程中的典型生物标志物变化特点,提出判识混源油组成的可能标志。据此标准,查清了研究区现有侏罗系原油和油砂的分布特点,再结合侏罗系烃源岩的分布情况,认为本区侏罗系原油可望具有良好的勘探前景,应重视对其勘探和研究。

准噶尔盆地中部侏罗系三工河组储层沥青地球化学特征及其对油气成藏过程的指示

准噶尔盆地中部地区侏罗系三工河组储层中广泛发育固体沥青,记录了重要的油气成藏信息。基于岩相学、反射率、激光拉曼光谱和生物标志化合物等多方面的综合分析,结合构造和成藏演化史,探讨了沥青的成因、来源及其对油气成藏的指示意义。研究区三工河组储层沥青主要赋存在构造缝中,裂缝面存在弯曲变形,矿物显微构造变形明显,指示沥青形成与构造活动破坏古油藏有关。沥青的生物标志化合物特征与油源对比结果指示沥青主要来源于二叠系风城组和下乌尔禾组的烃源岩,具有混源成藏特征。沥青成熟度较低(等效镜质体反射率为0.62%~0.79%),且具强烈生物降解特征,说明为生物降解成因沥青,同时生物标志物指示沥青受到晚期原油充注的影响。古油藏成藏时间在中侏罗世车—莫古隆起形成初期,晚侏罗世—早白垩世古隆起抬升遭受强烈剥蚀,古油藏遭受破坏进而引发轻烃组分散逸,并伴随生物降解作用演化形成沥青。早白垩世,下乌尔禾组烃源岩晚期油气开始充注后,三工河组储层没有再发生强烈构造活动,随储层再次埋深和油气充注,最终形成现今油气藏。虽然研究区三工河组储层曾经历构造活动调整,但油气的再次充注使其仍成为有利的勘探对象。

准噶尔盆地中部1区块侏罗系三工河组毯砂成岩演化及其物性演化分析

通过储层镜下观察分析,研究准中1区块三工河组二段毯砂储层的微观特征;根据自生矿物之间的交代关系及矿物的溶解—充填等现象,分析各成岩作用发生的先后顺序;结合油气充注史研究,建立储层成岩演化序列与油气充注的耦合关系,分析主成藏期毯砂的物性及其输导能力.结果表明:该毯砂受成岩作用改造强烈,现今储层物性整体以低孔低渗为主,孔隙类型主要为次生溶蚀孔,储层经历多期溶解、多期胶结的过程,并伴随多期油气充注;在主成藏期,毯砂埋藏较浅,处于成岩早期,物性较好,可成为较好的横向输导层,在油源断层较少的情况下,与各级断层一起构成断—毯式输导体系,使油气得以大范围输导.

基于改进层次熵分析法的致密砂岩储层可压性评价——以准噶尔盆地Z109井侏罗系储层为例

储层可压裂性评价是储层改造方案设计的重要依据,影响致密砂岩可压裂性的主要因素有天然裂缝、砂岩脆性、水平应力差异、断裂韧性等。研究以准噶尔盆地中部1区块Z109井侏罗系致密砂岩为例,综合考虑天然裂缝、砂岩脆性、水平应力差异、断裂韧性四种影响因素,采用改进的层次分析和熵值法相结合的方法进行了致密砂岩储层可压裂性评价。研究结果表明:可压裂性指数越大,致密砂岩储层越易于压裂,压裂时越能获得较复杂的裂缝网络;可压裂性指数大于0.44,砂岩脆性高,断裂韧性小,裂缝发育程度高,水平差异系数小的储层段为Ⅰ级优质压裂层;可压裂性指数大于0.44,砂岩脆性高,断裂韧性小,裂缝发育程度低,水平差异系数大的储层段为Ⅱ级可压裂层;研究区Z109井4036~4039 m、4062~4067 m、4214~4218 m和4260~4272 m为Ⅰ级优质压裂层,4093~4108 m和4284~4313 m为Ⅱ级可压裂层。研究成果可为致密砂岩压裂改造提供科学依据。

准噶尔盆地中央坳陷西部下组合油气成藏模式及勘探前景

准噶尔盆地中央坳陷西部下组合具备形成大油气田的有利条件,勘探程度较低,是重要的战略勘探领域。通过系统梳理中央坳陷西部下组合构造、源岩、储层及成藏要素配置关系,建立成藏模式,优选有利区带。研究认为:中央坳陷西部发育石炭系、下二叠统佳木河组和风城组、中二叠统下乌尔禾组3套规模烃源岩,其中风城组是优质碱湖烃源岩,生烃潜力大,与伸入玛湖凹陷内的下组合构造圈闭直接接触,源-储配置关系好。下组合发育火山岩、泥质白云岩和碎屑岩3类储层,在风城组区域性云质泥岩盖层的遮挡下形成有利储-盖组合。下组合普遍发育超压,埋深6200 m以深油气相态以凝析油和天然气为主,易于形成高产。根据源-储对接关系,建立了源边披覆型、源边侧接型和源内叠覆型3种成藏模式,其中源边侧接型和源内叠覆型圈闭目的层与烃源岩之间发育大型供烃窗,成藏条件优越。评价优选盆1井西凹陷东北环带、莫索湾凸起、玛中构造带、沙湾凹陷西环带和达巴松鼻凸带等5个有利勘探区带,是下组合油气勘探获得战略突破的重要区带。

准噶尔盆地中部地区侏罗系压扭断裂体系样式及其控藏作用研究

中国西部盆地的腹部压扭断裂体系比较发育,但对其断裂组合样式及其成因机制认识程度较低,这已成为重点勘探领域由盆缘向盆内战略展开的瓶颈问题。基于对准噶尔盆地中部地区侏罗系多个构造单元压扭断层几何学特征及其应力-应变状态分析,明确了燕山Ⅱ幕压扭断层是深部基底强烈压扭形变发育至中浅层的直接响应,具有以压为辅、以扭为主的成因机制。与准中地区"棋盘格"底形构造密切相关,侏罗系压扭断层具有"三带一区"四类典型组合样式和展布规律。两组不同走向断层大致呈共轭剪切关系,在平面上构成完整或不完整菱形几何学形态。据库伦破裂准则和地震剖面特征可判识出,锐角区具有明显挤压性质,而钝角区具有伸展性质。较高勘探程度区块钻探成果及试油效果证实,锐角挤压区断面封闭性较好,是油气主要富集单元;钝角伸展区断面普遍开启,是油气纵向输导区。研究成果反映了我国西部陆内坳陷区压扭断裂体系组合样式、成因机制及其控藏作用研究的新进展,对准中地区侏罗系下一步油气勘探具有很大启示意义。

准噶尔盆地中部4区块白垩系清水河组沉积特征研究

准噶尔盆地中部4区块白垩系为一套潜力层系,但研究程度相对较低,制约了该区域的勘探进程。根据测、录井及地震等资料,对准噶尔盆地中部4区块白垩系清水河组(K1q)层序发育特征及沉积相开展了研究。结果表明,K1q可划分为2个三级层序,进而将其分为清水河组一段(K1q1)、二段(K1q2),每个三级层序内又可进一步划分为水进体系域和水退体系域;其中K1q1主要发育辫状河沉积,砂体厚度大,横向分布广,以寻找低幅构造圈闭和岩性超覆体为主要勘探目标;K1q2则主要发育三角洲-滨浅湖滩坝沉积体系,储层整体不甚发育,主要以寻找三角洲和滩坝砂形成的岩性圈闭为主要勘探目标。在相序上,K1q2的三角洲-滨浅湖沉积体系直接覆盖于K1q1的辫状河沉积之上,这一垂向相序在研究区是合理的。

准噶尔盆地中S区西山窑组沉积微相与油气勘探

准噶尔盆地中部S区块是老油盆的新区块,其重点勘探层位西山窑组,已有工业性油气产出.综合分析了沉积微相与油气勘探的关系,采用"点-线-面"的立体空间研究思路,作出了三维的微相划分和相关的4种有利储层类型划分.中S区西山窑组沉积特征是,整体处于水退的环境中,兼有短期的水进,其中Y1井区主要经历了浅湖-湖沼-辫状河三角洲前缘-滨湖相,最有利微相是2砂组的辫状河三角洲前缘水下分流河道.

准噶尔盆地腹部超压演化及成因

准噶尔盆地腹部超压分布广泛,演化历史长,形成机制复杂。采用数值模拟技术,动态恢复了单井和二维剖面的超压演化历史,并基于不同机制对超压形成贡献量的定量分析,探讨了超压主要成因。准噶尔盆地腹部单井超压演化可划分为2个增压阶段,历经"一个半"压力旋回;剖面上发育深部和浅部2套分别以下二叠统和侏罗系为中心的相对独立的超压系统,其中深部超压系统发育时间早,在燕山运动期间曾经历明显的泄压过程,现今超压中心主要位于昌吉凹陷东部的深洼内;浅部超压系统形成时间相对较晚,其横向展布范围广,断层对超压分布具一定的分割作用;深部超压主要源于欠压实作用,浅部超压的形成主要与欠压实和石英胶结作用有关。

准噶尔盆地中部凹陷区二叠系—三叠系油气成藏主控因素与勘探方向

准噶尔盆地近年在中央坳陷边缘斜坡区二叠系上乌尔禾组、三叠系百口泉组连续获得重大油气发现,但盆地中部凹陷区针对该领域的钻探仅2口井获低产而多口井目的层未见油气显示,因此亟需深化该地区的油气成藏认识,明确其主控因素。通过对中部凹陷区成藏条件的分析,结合已钻井成藏分析,明确凹陷区失利井未获油气发现的直接原因为局部“通源断裂”不发育和储层物性差。基于此,建立了凹陷区二叠系—三叠系油气藏“通源断裂”、“优质砂体”二元控藏的下生上储成藏模式。根据“通源断裂”与砂体的配置关系,明确地层超覆背景下的上乌尔禾组、百口泉组低位扇三角洲前缘砂体岩性油气藏是下步风险勘探的首选领域,有利区面积约3 600 km^(2);中—下二叠统烃源岩层系内的非常规油气和源外多层系常规油气综合勘探是未来主要勘探方向。