松辽盆地南部红岗油田青山口组片钠铝石的结晶特征及成因探讨

松辽盆地南部红岗油田青山口组发育大量含片钠铝石砂岩。含片钠铝石砂岩的岩石类型为长石岩屑砂岩和岩屑长石砂岩,砂岩中的胶结物主要为次生加大石英、方解石、片钠铝石、铁白云石和粘土矿物,成岩共生序列为粘土包壳-方解石-石英次生加大-片钠铝石-铁白云石-沥青。其中,片钠铝石多以放射状、栉状、板状等集合体充填孔隙,少量以杂乱状和板状交代长石和岩屑,且交代的碱性长石多于斜长石;此外,孔隙中的放射状片钠铝石开始生长时多呈团簇状,随埋深的增大,放射状及栉状片钠铝石的晶体平均粒度变大,板状片钠铝石的含量也增加;而片钠铝石的总含量则先增加后减少,片钠铝石的结晶特征及其含量与成岩流体的温度的高低、pH值的大小以及CO₂分压的高低等密切相关。     

松辽盆地红岗油田白垩系青山口组含片钠铝石砂岩自生矿物共生序列

松辽盆地红岗油田白垩系青山口组发育含片钠铝石砂岩。通过偏光显微镜、扫描电镜、阴极发光 仪、Ｘ射线衍射等多种技术手段,对含片钠铝石砂岩的碎屑成分、胶结物类型及自生矿物共生序列等特征进行 了研究。该区含片钠铝石砂岩为岩屑长石砂岩及长石岩屑砂岩,胶结物有次生加大长石、次生加大石英、自生 石英微晶、黏土矿物、片钠铝石、方解石、铁方解石及铁白云石。方解石的形成分为两期,第１期方解石为原 始生物碎屑颗粒溶蚀溶解的产物,第２期方解石可能与ＣＯ^２ 充注后钙长石及早期碳酸盐矿物的溶蚀溶解有关。 含片钠铝石砂岩的自生矿物共生序列为：次生加大长石、早期次生加大石英-自生石英微晶-早期高岭石、第１ 期方解石、片钠铝石-晚期次生加大石英-晚期高岭石、第２期方解石、铁方解石、铁白云石。其中ＣＯ^２ 注入 后的矿物共生组合为：片钠铝石-晚期次生加大石英-晚期高岭石、第２期方解石、铁方解石、铁白云石。     

松辽盆地南部乾安油田青山口组含片钠铝石砂岩的成岩作用

松辽盆地南部乾安油田青山口组发育大量含片钠铝石砂岩.通过偏光显微镜、扫描电镜、茜素红-S染色和X-射线衍射分析等,对含片钠铝石砂岩的骨架碎屑成分、胶结物与自生矿物、成岩共生序列和流体演化等进行了系统研究.结果表明:松辽盆地南部乾安油田含片钠铝石砂岩的粒度为粉砂、微粒-细粒,分选中-好,岩石类型为微粒含片钠铝石长石砂岩、微粒含片钠铝石岩屑长石砂岩.胶结物与自生矿物主要为片钠铝石、铁白云石、方解石、次生加大石英、自生粘土矿物(高岭石及伊利石).片钠铝石一部分以放射状、束状和板状等产出,另一部分呈凝块状大面积地连片出现,尤为特殊.成岩共生序列依次为方解石-自生高岭石、次生加大石英-伊利石-片钠铝石、铁白云石.CO2注入前形成的自生矿物组合主要为多期方解石组合,高岭石、次生加大石英组合;CO2注入之后形成了片钠铝石和铁白云石组合.流体演化过程为碱性流体环境-酸性流体环境-酸性流体向碱性流体过渡或偏碱性流体环境-碱性流体环境.     

海拉尔盆地乌尔逊凹陷与松辽盆地孤店CO2气田含片钠铝石砂岩的岩石学特征

海拉尔盆地乌尔逊凹陷南屯组与松辽盆地孤店CO₂气田泉头组发育大量含片钠铝石砂岩。通过偏光显微镜、扫描电镜、茜素红-S染色、X射线衍射、电子探针与INCA能谱分析等,对含片钠铝石砂岩的骨架碎屑组分、胶结物与自生矿物、成岩共生序列等岩石学特征进行了系统研究。研究表明,含片钠铝石砂岩的岩石类型为长石砂岩和岩屑长石砂岩,粒度以细粒、细-中粒为主,分选差-中等。砂岩中胶结物主要为次生加大石英、自生石英、片钠铝石、铁白云石和粘土矿物。其中,片钠铝石最高可达砂岩总体积的22％在砂岩中或以放射状、束状、菊花状、杂乱毛发状、毛球状、板状等集合体充填孔隙,或呈束状和板状交代长石和岩屑。电子探针与INCA能谱综合分析表明,片钠铝石主要由Na、Al、O、C等组成。在含片钠铝石砂岩中,成岩共生序列依次为粘土矿物包壳-次生加大石英、自生石英、自生高岭石-油气充注-CO₂充注-片钠铝石-铁白云石。其中,CO₂注入前形成的自生矿物组合主要为次生加大石英、自生石英和自生高岭石,CO₂注入后形成的自生矿物组合主要为片钠铝石和铁白云石。     

海拉尔盆地贝尔凹陷含片钠铝石沉凝灰岩的成岩作用

以海拉尔盆地贝尔凹陷大磨拐河组—伊敏组的含片钠铝石火山碎屑岩为研究对象,采用偏光显微镜、扫描电镜及配套能谱、茜素红-S染色、阴极发光和X-射线衍射分析等技术手段,对研究样品的岩石类型、自生矿物种类及共生序列进行了详细研究.贝尔凹陷发育片钠铝石的宿主岩石类型为沉凝灰岩,自生矿物以发育片钠铝石、铁白云石和菱铁矿三种碳酸盐矿物为主,片钠铝石含量高达25％.成岩共生序列为菱铁矿Ⅰ→高岭石、石英次生加大→片钠铝石→微晶石英→方解石→铁白云石→菱铁矿Ⅱ→沥青.不同于国内外其它地区发现片钠铝石的主要产状为充填孔隙,本区内发育的片钠铝石以交代长石、石英、岩屑颗粒和高岭石基质为赋存特征,表明沉凝灰岩中的长石、岩屑、高岭石基质可以为其提供金属离子物质来源,并在CO2参与下,与成岩流体反应生成片钠铝石.大量碳酸盐矿物(15-44％)的发育证明了火山碎屑岩具有较高的CO2矿物捕获能力.     

海拉尔盆地乌尔逊凹陷与松辽盆地孤店C02气田含片钠铝石砂岩的岩石学特征

海拉尔盆地乌尔逊凹陷南屯组与松辽盆地孤店CO2气田泉头组发育大量含片钠铝石砂岩.通过偏光显微镜、扫描电镜、茜素红-S染色、X射线衍射、电子探针与INCA能谱分析等,对含片钠铝石砂岩的骨架碎屑组分、胶结物与自生矿物、成岩共生序列等岩石学特征进行了系统研究.研究表明,含片钠铝石砂岩的岩石类型为长石砂岩和岩屑长石砂岩,粒度以细粒、细-中粒为主,分选差-中等.砂岩中胶结物主要为次生加大石英、自生石英、片钠铝石、铁白云石和牯土矿物.其中,片钠铝石最高可达砂岩总体积的22%,在砂岩中或以放射状、束状、菊花状、杂乱毛发状、毛球状、板状等集合体充填孔隙,或呈束状和板状交代长石和岩屑.电子探针与INCA能谱综合分析表明,片钠铝石主要由Na、AI、O、C等组成.在含片钠铝石砂岩中,成岩共生序列依次为牯土矿物包壳-次生加大石英、自生石英、自生高岭石-油气充注-CO2充注-片钠铝石-铁白云石.其中,CO2注入前形成的自生矿物组合主要为次生加大石英、自生石英和自生高岭石,C02注入后形成的自生矿物组合主要为片钠铝石和铁白云石.     

松辽盆地南部红岗背斜幔源-岩浆成因CO2大规模泄露的岩石学记录

通过片钠铝石自生矿物的时空分布、产状和含片钠铝石砂岩中流体包裹体特征的研究,揭示了松辽盆地南部红岗背斜CO2大规模渗漏的岩石学记录。在红岗背斜,片钠铝石主要分布于白垩系青山口组,其次为泉头组和姚家组。绝大部分含片钠铝石砂岩中不含CO2,部分含片钠铝石砂岩发育层段为油层。片钠铝石含量与沥青含量呈弱正相关,沥青普遍分布于油层和干层中。在含片钠铝石砂岩中发育CO2充注前和充注后2个成岩共生组合。其中:在CO2充注前形成的成岩共生组合中,赋存以液烃包裹体为主的第一期油气包裹体;在CO2充注后形成的成岩共生组合中,赋存以气液烃包裹体为主的第二期油气包裹体。研究表明,CO2大规模泄露的岩石学记录主要为广泛分布的、赋存于非CO2气藏中的片钠铝石自生矿物和沥青。前者是CO2大规模泄露的重要标志,后者是CO2渗漏过程中由于地层压力降低,引起原油轻重组分分离而形成的。红岗断层可能是CO2大规模泄露的通道,其渗漏时间应该不晚于明二段沉积之前。     

海拉尔盆地乌尔逊凹陷无机CO_2充注驱油的流体包裹体证据

CO2充注驱油是一种普遍的地质现象,对揭示油气藏中油气的动态成藏规律具有重要的指示意义.海拉尔盆地乌尔逊凹陷含片钠铝石砂岩既示踪了CO2充注,又记录了油气充注,是进行CO2充注驱油研究的理想岩石类型.通过岩石学和流体包裹体地球化学研究,确定了含片钠铝石砂岩的成岩共生序列、油气充注历史和CO2充注驱油的微观证据.研究表明,该区油气充注是一个连续的过程,开始于石英次生加大早期(120 Ma),在片钠铝石沉淀前(105～95 Ma)达到充注高峰.CO2充注晚于大规模油气充注,充注之后形成的自生矿物组合为片钠铝石与铁白云石.片钠铝石中首次发现一定数量的原生油气包裹体,为CO2充注驱油提供了重要的微观证据.     

海拉尔盆地乌尔逊凹陷片钠铝石及研究意义

海拉尔盆地乌尔逊凹陷含片钠铝石砂岩与CO2气井、燕山期花岗岩的分布一致,均产于苏仁诺尔构造带乌西断裂控制的区域.在偏光显微镜和扫描电镜下观察发现片钠铝石的产状有3种:①部分或全部交代长石、石英等碎屑颗粒,多呈长柱状、片板状集合体;②作为胶结物充填于碎屑颗粒间的孔隙中,呈放射状、束状、毛发状、菊花状集合体;③充填在碎屑矿物的溶洞或裂隙中,呈纤维状集合体.含片钠铝石砂岩的成岩共生序次和油气包裹体及现今地层水特征均表明,片钠铝石的生长时间晚于任何其它自生矿物.电子探针及INCA能谱仪分析表明,片钠铝石主要由Na、Al、O、C等组成.研究表明,海拉尔盆地乌尔逊凹陷片钠铝石可作为深部CO2热流体活动的示踪矿物.     

海拉尔盆地贝尔凹陷含片钠铝石沉凝灰岩的成岩作用

以海拉尔盆地贝尔凹陷大磨拐河组-伊敏组的含片钠铝石火山碎屑岩为研究对象,采用偏光显微镜、扫描电镜及配套能谱、茜素红 S染色、阴极发光和X 射线衍射分析等技术手段,对研究样品的岩石类型、自生矿物种类及共生序列进行了详细研究。贝尔凹陷发育片钠铝石的宿主岩石类型为沉凝灰岩,自生矿物以发育片钠铝石、铁白云石和菱铁矿三种碳酸盐矿物为主,片钠铝石含量高达25%。成岩共生序列为菱铁矿Ⅰ→高岭石、石英次生加大→片钠铝石→微晶石英→方解石→铁白云石→菱铁矿Ⅱ→沥青。不同于国内外其它地区发现片钠铝石的主要产状为充填孔隙,本区内发育的片钠铝石以交代长石、石英、岩屑颗粒和高岭石基质为赋存特征,表明沉凝灰岩中的长石、岩屑、高岭石基质可以为其提供金属离子物质来源,并在CO2参与下,与成岩流体反应生成片钠铝石。大量碳酸盐矿物（15-44%）的发育证明了火山碎屑岩具有较高的CO2矿物捕获能力。     

Controlling factors for dawsonite diagenesis: a case study of the Binnan Region in Dongying Sag,Bohai Bay Basin,China

Authigenic minerals and the diagenetic sequence of the dawsonite-bearing sandstones from the Binnan Region of the Dongying Sag, Bohai Bay Basin, China were studied to understand the formation of dawsonite, as a possible mechanism for mineral trapping of CO₂ in carbon capture and storage (CCS) programmes. Authigenic minerals include quartz overgrowth, dawsonite (5–15 vol%), calcite, ferrocalcite and ankerite. The major rock types are medium- to fine-grained arkose, feldspathic litharenite and lithic arkose. Quantitative analysis suggests that the burial depth and feldspar content are the two dominant controlling factors of the growth of dawsonite. The dawsonite content increases initially before decreasing with burial depth, with the peak dawsonite content occurring at approximately 1500 m depth. This trend is probably due to increases in temperature and pCO₂ with the burial depth and contributes to the formation of dawsonite. However, the pCO₂ content and stability of dawsonite decrease with increasing distance from the centre of the gas reservoir. When the formation temperature exceeds the upper limit of the preservation temperature of dawsonite, the dawsonite is suppressed, while the dissolution of dawsonite is promoted. Overall, the dawsonite content exhibits a positive correlation with the feldspar content. The dissolution of feldspar makes both Na⁺ and Al³⁺ available and creates the accommodation space necessary for dawsonite growth. In addition, feldspar dissolution also neutralises the acidity of the thermal fluid present, which again facilitates the growth and preservation of the dawsonite.     

Diagenesis and Fluid Flow History in Sandstones of the Upper Permian Black Jack Formation, Gunnedah Basin, Eastern Australia

The fluid flow history during diagenesis of sandstones in the Upper Permian Black Jack Formation of the Gunnedah Basin has been investigated through integrated petrographic observations, fluid inclusion investigations and stable isotope analyses. The early precipitation of mixed-layer illite/smectite, siderite, calcite, ankerite and kaolin proceeded at the presence of Late Permian connate meteoric waters at temperatures of up to 60℃. These evolved connate pore waters were also parental to quartz, which formed at temperatures of up to 87℃. The phase of maximum burial was characterized by development of filamentous illite and late calcite at temperatures of up to -90℃. Subsequent uplifting and cooling led to deep meteoric influx from surface, which in turn resulted in dissolution of labile grains and carbonate cements, and formation of second generation of kaolin. Dawsonite was the last diagenetic mineral precipitated and its formation is genetically related to deep-seated mamagtic sourced CO2.     

内蒙古白乃庙矿田十四万金矿床流体包裹体研究

十四万金矿床是白乃庙矿田徐尼乌苏金矿化带内重要的石英脉型金矿,矿体产于EW向韧性剪切带的次级NE向断裂.成矿过程划分为3个阶段:早阶段形成无矿石英脉,石英遭受明显压应力作用,包裹体类型包括富水溶液型、富碳质型、纯碳质型,包裹体均一温度为260～420℃,平均盐度6.78%NaCl eqv;中阶段为硫化物-方解石-绿泥石-绢云母-细粒石英组合,充填早阶段石英的裂隙,未遭受明显应力作用,包裹体类型为富水溶液型和纯碳质型,包裹体均一温度为140～260℃,平均盐度7.22%NaCl eqv;晚阶段形成方解石脉,仅有富水溶液型包裹体,包裹体均一温度为140～180℃,平均盐度2.15%NaCl eqv.激光拉曼测试结果表明包裹体气相成份主要为CO_2、CH_4和少量N2.早阶段成矿流体为富碳质流体,成分为CH_4+CO_2+H_2O,中阶段流体为富水流体,成分为H_2O+CH_4,早、中阶段均发生了流体沸腾作用,早阶段强烈的沸腾作用使流体CO_2和CH_4含量降低,中阶段方解石沉淀使CO_2含量进一步降低,并导致了硫化物沉淀和金矿化.十四万金矿床流体包裹体特征、矿床地质特征均与造山型矿床一致,为造山型金矿,成矿流体可能源于徐尼乌苏组浅变质作用产生的变质流体,成矿构造背景可能为二叠纪末-三叠纪初华北板块与西伯利亚板块间的陆陆碰撞造山体制.     

鄂尔多斯盆地中西部长8砂岩的流体包裹体特征与油气成藏期次分析

利用流体包裹体的分析测试技术与研究方法,对鄂尔多斯盆地中西部长8油层组的成藏期次进行了研究。烃类包裹
体及其伴生的盐水包裹体的岩相学特征、均一温度、盐度、密度及成分分析显示,长8储层主要发育两期烃类包裹体,第
一期分布在早期方解石胶结物、石英颗粒表面及其连生的石英加大边中以及未切穿石英颗粒的早期愈合裂缝中,其伴生盐
水包裹体的均一温度峰值为80~90℃;第二期烃类包裹体分布在石英颗粒表面和切穿石英颗粒的裂缝中,其伴生盐水包裹
体的均一温度峰值为100~120℃。储层成岩作用与油气充注微观分析、成岩-烃类充注演化时间序列研究,结合地层埋藏史
和热史分析表明,研究区经历了三期烃类充注事件：第一期（约169~161 Ma） 充注规模小,砂岩中未捕获到这一期适合进
行均一温度与成分测定的烃类包裹体,因此本研究缺乏这期包裹体的温度与成分数据;第二期（约148~135 Ma） 烃类充注
对应前述获得均一温度与成分数据的第一期烃类包裹体;第三期烃类充注规模最大,发生在早白垩世晚期的125.2~105.7 Ma
之间,为主成藏期,对应前述获得均一温度与成分数据的第二期烃类包裹体。     

Opal and chalcedony speleothems on quartz sandstones in the Sydney region,southeastern Australia

Speleothems of silica are far rarer than those of calcite but occur in a range of types including stalactites, stalagmites and flowstones. This study has found a wider range and far greater number of silica speleothems on the quartz sandstones of the Sydney region than the small number of previous accounts had suggested. Speleothems on the Sydney region sandstones are composed of multiple layers of amorphous opal‐A and cryptocrystalline chalcedony. Silica slowly dissolved from detrital and diagenetic quartz and kaolinite clays of the host arenites is redeposited as opal‐A at the sandstone surface when groundwater evaporates. This amorphous silica converts over time by Ostwald‐type paragenesis to the cryptocrystalline form, but the expected intermediate opal‐CT phase has not been detected. The crystallisation of chalcedony at earth‐surface temperatures is generally believed to take an extremely long time and its presence makes these speleothems very significant, especially as it is reported in only a small number of silica speleothems elsewhere. Furthermore, a similar paragenetic silica‐‘ripening’ mechanism may also be involved in the low‐temperature earth‐surface formation of other crystalline silica deposits such as silcrete duricrusts and pedogenic quartz. Additional closely coupled laboratory and field investigations into the processes that control silica paragenesis under earth‐surface conditions are sorely needed.     

Diagenesis and Diagenetic Evolution of Deltaic and Neritic Gas-Bearing Sandstones in the Lower Mingyuefeng Formation of Paleogene, Lishui Sag, East China Sea Shelf Basin: Implications for Depositional Environments and Sequence Stratigraphy Controls

Gas-bearing deposits in the Lower Mingyuefeng Formation of Paleogene, Lishui Sag, East China Sea Shelf Basin consist of shoreface sandstones of the highstand systems tract (HST) and transgressive systems tract (TST), and deltaic sandstones of the lowstand systems tract (LST) and falling stage systems tract (FSST). Detailed petrographic observations suggest that the diagenetic features and related evolution of these deposits cannot be simply characterized and demonstrated in the depth domain. However, the occurrence of diagenetic minerals systematically depends on the studied interval within the HST, TST, LST, and FSST; therefore, diagenesis in this region can be better constrained when studied in the context of the depositional environments and sequence stratigraphic framework. The eogenetic processes in such settings include: (1) microcrystalline siderite precipitated as concretions in almost all environments and systems tracts, which inhibited further mechanical compaction; (2) grain dissolution and kaolinitization occurred in shoreface HST sandstones and deltaic LST and FSST sandstones; (3) glaucony was locally observed, which did not clearly reflect the controls of facies or sequence stratigraphy; and (4) cementation by pyrite aggregates occurred in the shoreface HST sandstones and deltaic LST sandstones. The mesogenetic diagenesis includes: (1) partial conversion of kaolinite into dickite in deltaic LST sandstones, and minor chlorite cementation in deltaic FSST sandstones; (2) transformation of kaolinite into illite and quartz cementation in deltaic LST and FSST sandstones; (3) frequent precipitation of ankerite and ferroan calcite in shoreface TST sandstones and early HST sandstones, forming baffles and barriers for fluid flow, with common calcite in shoreface HST sandstones as a late diagenetic cement; and (4) formation of dawsonite in the deltaic LST and FSST sandstones, which is interpreted to be a product of the invasion of a CO2-rich fluid, and acts as a good indicator of CO2-bearing reservoirs. This study has thus constructed a reliable conceptual model to describe the spatial and temporal distribution of diagenetic alterations. The results may provide an entirely new conceptual framework and methodology for successful gas exploration in the continental margins of offshore China, thus allowing us to predict and unravel the distribution and quality evolution of clastic reservoirs at a more detailed and reliable scale.     

鄂尔多斯盆地南部延长组重力流致密储层成岩作用及物性演化

成岩作用及物性演化的研究对致密砂岩储层和致密油开发具有重要意义.综合利用岩石铸体薄片鉴定、扫描电镜、X衍射分析、流体包裹体分析等测试手段,对研究区致密储层进行详细研究.研究表明:深水重力流砂体粒度细,孔喉组合以细孔-微喉型为主,物性差,是一套典型的特低渗透储层;目前正处于中成岩B期,其成岩演化序列为:机械压实作用/方解石胶结→凝灰物质水解蚀变/云母水化/伊利石胶结/绿泥石胶结/石英溶蚀→早期长石溶蚀/石英加大/碳酸盐灰泥重结晶/早期碳酸盐胶结物溶蚀→晚期长石溶蚀→铁方解石胶结,成岩环境主要经历了碱性→酸性→弱碱性的转换过程;距今约99~118 Ma的早白垩世,研究区储层发生了连续的2期油气充注;储层物性演化史表明早成岩期储层的成岩作用对储层物性影响大,使储层已经致密化,研究区具有先致密后成藏的特性.      

Diagenesis in the Middle Jurassic Khatatba Formation sandstones in the Shoushan Basin,northern Western Desert,Egypt

The Middle Jurassic Khatatba Formation acts as a hydrocarbon reservoir in the subsurface in the Western Desert, Egypt. This study, which is based on core samples from two exploration boreholes, describes the lithological and diagenetic characteristics of the Khatatba Formation sandstones. The sandstones are fine‐ to coarse‐grained, moderately to well‐sorted quartz arenites, deposited in fluvial channels and in a shallow‐marine setting. Diagenetic components include mechanical and chemical compaction, cementation (calcite, clay minerals, quartz overgrowths, and a minor amount of pyrite), and dissolution of calcite cements and feldspar grains. The widespread occurrence of an early calcite cement suggests that the Khatatba sandstones lost a significant amount of primary porosity at an early stage of its diagenetic history. In addition to calcite, several different cements including kaolinite and syntaxial quartz overgrowth occur as pore‐filling and pore‐lining cements. Kaolinite (largely vermicular) fills pore spaces and causes reduction in the permeability of the reservoir. Based on framework grain–cement relationships, precipitation of the early calcite cement was either accompanied by or followed the development of part of the pore‐lining and pore‐filling cements. Secondary porosity development occurred due to partial to complete dissolution of early calcite cements and feldspar. Late kaolinite clay cement occurs due to dissolved feldspar and has an impact on the reservoir quality of the Khatatba sandstones. Open hydraulic fractures also generated significant secondary porosity in sandstone reservoirs, where both fractures and dissolution took place in multiple phases during late diagenetic stages. The diagenesis and sedimentary facies help control the reservoir quality of the Khatatba sandstones. Fluvial channel sandstones have the highest porosities and permeabilities, in part because of calcite cementation, which inhibited authigenic clays or was later dissolved, creating intergranular secondary porosity. Fluvial crevasse‐splay and marine sandstones have the lowest reservoir quality because of an abundance of depositional kaolinite matrix and pervasive, shallow‐burial calcite and quartz overgrowth cements, respectively. Copyright © 2013 John Wiley & Sons, Ltd.