RESERVOIR CHARACTERISTICS OF JURASSIC SHAXIMIAO FORMATION, WESTERN SICHUAN BASIN

研究表明，川西地区沙溪庙组储层主要储集岩为长石砂岩、岩屑长石砂岩，其次为岩屑砂岩、长石岩屑砂岩及岩屑石英砂岩。储集空间分为孔、缝，其中主要储集空间为粒间溶孔，其次为残余粒间孔和粒内溶孔。喉道类型以管状和粒间裂隙为主，属细一微喉型。储层孔隙结构差，具有孔隙小、喉道窄、有效连通孔隙体积小和中一高排驱压力的特征，总体属于低一中孔、低一中渗，局部存在高孔高渗的常规储层，非均质性强。在此基础上通过对储层发育控制因素、储集砂体展布及有利储集区带的研究，为川西沙溪庙组的油气藏勘探开发提供了重要支撑。

The Uplift of the Longmenshan Thrust Belt and Subsidence of the West Sichuan Foreland Basin

Based on fission track dating of apatite, and measurement of vitrinite reflectance of rock samples from the Longmenshan (Longmen Mountain)area and the West Sichuan foreland basin and computer modelling it is concluded that (l)the Songpan-Garze fold belt has uplifted at least by 3-4 km with an uplift rate of no less than 0.3-0.4 mm/a since 10 Ma B.P.; (2) the Longmenshan thrust nappe belt has uplifted at least by 5-6 km with an uplift rate of more than 0.5- 0.6 mm /a since 10 Ma B.P.; (3) the Longmenshan detachment belt has uplifted by 1 - 2 km at a rate of 0.016-0.032 mm/a since 60 Ma B.P.; (4) the West Sichuan foreland basin has uplifted by 1.7-3 km at a rate of 0.028-0.05 mm/a since 60 Ma B.P.; (5) the uplift rate of the area on the west side of the Beichuan-Yingxiu-Xiaoguanzi fault for the last 10 Ma is 40 times as much as that on its east side; (6) the uplifting of the the Songpan - Garze fold belt and the subsidence of the West Sichuan foreland basin 60 Ma ago exhibit a mirro-image correlation, i.e. the rapid uplifting of the the Songpan-Garze fold belt was corresponding to the rapid subsidence of the basin;the Songpan-Garze fold belt has uplifted at a much greater rate than the West Sichuan foeland basin in the last 60 Ma;and (7) the palaeogeothermal gradient was 25℃ /km in the West Sichuan foreland basin.

Tectonic Fractures in Tight Gas Sandstones of the Upper Triassic Xujiahe Formation in the Western Sichuan Basin,China

The western Sichuan Basin, which is located at the front of the Longmen Mountains in the west of Sichuan Province, China, is a foreland basin formed in the Late Triassic. The Upper Triassic Xujiahe Formation is a tight gas sandstone reservoir with low porosity and ultra-low permeability, whose gas accumulation and production are controlled by well-developed fracture zones. There are mainly three types of fractures developed in the Upper Triassic tight gas sandstones, namely tectonic fractures, diagenetic fractures and overpressure-related fractures, of which high-angle tectonic fractures are the most important. The tectonic fractures can be classified into four sets, i.e., N-S-, NE-, E-W- and NW-striking fractures. In addition, there are a number of approximately horizontal shear fractures in some of the medium-grained sandstones and grit stones nearby the thrusts or slip layers. Tectonic fractures were mainly formed at the end of the Triassic, the end of the Cretaceous and the end of the Neogene-Early Pleistocene. The development degree of tectonic fractures was controlled by lithology, thickness, structure, stress and fluid pressure. Overpressure makes not only the rock shear strength decrease, but also the stress state change from compression to tension. Thus, tensional fractures can he formed in fold-thrust belts. Tectonic fractures are mainly developed along the NE- and N-S-striking structural belts, and are the important storage space and the principal flow channels in the tight gas sandstone. The porosity of fractures here is 28.4% of the gross reservoir porosity, and the permeability of fractures being two or three grades higher than that of the matrix pores. Four sets of high-angle tectonic fractures and horizontal shear fractures formed a good network system and controlled the distribution and production of gas in the tight sandstones.

Characteristics of Triassic Petroleum Systems in the Longmenshan Foreland Basin,Sichuan Province,China

The Triassic in the Longmengshan foreland basin is rich in oil and gas resources. Its reservoirs feature low-porosity, low-permeability, small pore throat, high water saturation, and strong heterogeneity. The existence of abnormally high pressure and various reservoir-cap combinations developed at different times provide favorable conditions for trapping oil and gas. Taking the theory of petroleum systems as a guide, and beginning with research on tectonics, sedimentary history, distribution and evolution of source rocks, reservoir evolution, hydraulic force distribution, and hydrocarbon migration, analysis and study of static factors like source rocks, reservoirs and cap rocks, and dynamic factors such as hydrocarbon generation, migration, and accumulation revealed the characteristics of the Upper Triassic petroleum system in western Sichuan province. The deepbasin gas in the central hydrocarbon kitchen of the Upper Triassic, structural-lithological combination traps on the surrounding slopes, and the structural traps of the Indo-Chinese-Yangshan paleohighs, are potential plays. The relatively well- developed fault zones in the southern segment of the Longmengshan foothill belt are favorable Jurassic gas plays. Pengshan-Xinjin, Qiongxi, and Dayi are recent exploration targets for Jurassic oil/gas reservoirs.

The Coupling Relationship between the Uplift of Longmen Shan and the Subsidence of Foreland Basin,Sichuan,China

Depending on the analysis of the coeval sedimentary geometry and subsidence mechanism in the Longmen Shan foreland basin, three models about the coupling relationship between Longmen Shan uplift and foreland basin subsidence since the Indosinian have been proposed：（1） crustal shortening and its related wide wedge-shaped foreland basin,（2） crustal isostatic rebound and its related tabular foreland basin, and（3） lower crustal flow and its related narrow wedge-shaped foreland basin. Based on the narrow wedge-shaped foreland basin developed since 4 Ma, it is believed that the narrow crustal shortening and tectonic load driven by lower crustal flow is a primary driver for the present Longmen Shan uplift and the Wenchuan（Ms 8.0） earthquake.

Oil and Gas Accumulation in the Foreland Basins,Central and Western China

Foreland basin represents one of the most important hydrocarbon habitats in central and western China. To distinguish these foreland basins regionally, and according to the need of petroleum exploration and favorable exploration areas, the foreland basins in central and western China can be divided into three structural types： superimposed, retrogressive and reformative foreland basin （or thrust belt）, each with distinctive petroleum system characteristics in their petroleum system components （such as the source rock, reservoir rock, caprock, time of oil and gas accumulation, the remolding of oil/gas reservoir after accumulation, and the favorable exploration area, etc.）. The superimposed type foreland basins, as exemplified by the Kuqa Depression of the Tarim Basin, characterized by two stages of early and late foreland basin development, typically contain at least two hydrocarbon source beds, one deposited in the early foreland development and another in the later fault-trough lake stage. Hydrocarbon accumulations in this type of foreland basin often occur in multiple stages of the basin development, though most of the highly productive pools were formed during the late stage of hydrocarbon migration and entrapment （Himalayan period）. This is in sharp contrast to the retrogressive foreland basins （only developing foreland basin during the Permian to Triassic） such as the western Sichuan Basin, where prolific hydrocarbon source rocks are associated with sediments deposited during the early stages of the foreland basin development. As a result, hydrocarbon accumulations in retrogressive foreland basins occur mainly in the early stage of basin evolution. The reformative foreland basins （only developing foreland basin during the Himalayan period） such as the northern Qaidam Basin, in contrast, contain organic-rich, lacustrine source rocks deposited only in fault-trough lake basins occurring prior to the reformative foreland development during the late Cenozoic, with hydrocarbon accumulations taking place relatively late （Himalayan period）. Therefore, the ultimate hydrocarbon potentials in the three types of foreland basins are largely determined by the extent of spatial and temporal matching among the thrust belts, hydrocarbon source kitchens, and regional and local caprocks.

Formation of overpressure system and its relationship with the distribution of large gas fields in typical foreland basins in central and western China

Based on the data of measured formation pressure, drilling fluid density of key exploration wells and calculated pressure by well logging, combined with the analysis of natural gas geological conditions, the characteristics and formation mechanisms of formation fluid overpressure systems in different foreland basins and the relationship between overpressure systems and large-scale gas accumulation are discussed.(1) The formation mechanisms of formation overpressure in different foreland basins are different. The formation mechanism of overpressure in the Kuqa foreland basin is mainly the overpressure sealing of plastic salt gypsum layer and hydrocarbon generation pressurization in deep–ultra-deep layers, that in the southern Junggar foreland basin is mainly hydrocarbon generation pressurization and under-compaction sealing, and that in the western Sichuan foreland basin is mainly hydrocarbon generation pressurization and paleo-fluid overpressure residual.(2) There are three common characteristics in foreland basins, i.e. superimposed development of multi-type overpressure and multi-layer overpressure, strong–extremely strong overpressure developed in a closed foreland thrust belt, and strong–extremely strong overpressure developed in a deep foreland uplift area.(3) There are four regional overpressure sealing and storage mechanisms, which play an important role in controlling large gas fields, such as the overpressure of plastic salt gypsum layer, the overpressure formed by hydrocarbon generation pressurization, the residual overpressure after Himalayan uplift and denudation, and the under-compaction overpressure.(4) Regional overpressure is an important guarantee for forming large gas fields, the sufficient gas source, large-scale reservoir and trap development in overpressure system are the basic conditions for forming large gas fields, and the overpressure system is conducive to forming deep to ultra-deep large gas fields.

Structural characteristics and implications on oil/gas accumulation in north segment of the Longmenshan piedmont,northwestern Sichuan Basin,SW China

By integrating surface geology,seismic data,resistivity sections,and drilling data,the structural deformation characteristics of the frontier fault of thrust nappes were delineated in detail.The frontier fault of thrust nappes in northwest Scihuan Basin is a buried thrust fault with partial exposure in the Xiangshuichang-Jiangyou area,forming fault propagation folds in the hanging-wall and without presenting large-scale basin-ward displacement along the gypsum-salt layer of the Triassic Jialingjiang Formation to the Triassic Leikoupo Formation.The southwestern portion of the frontier fault of thrust nappes(southwest of Houba)forms fault bend folds with multiple ramps and flats,giving rise to the Zhongba anticline due to hanging-wall slip along the upper flat of the Jialingjiang Formation.In contrast,the northeastern portion of the frontier fault of thrust nappes(northeast of Houba)presents upward steepening geometry,leading to surface exposure of Cambrian in its hanging-wall.With the frontier fault of thrust nappes as the boundary between the Longmenshan Mountain and the Sichuan Basin,the imbricated structural belt in the hanging-wall thrusted strongly in the Indosinian orogeny and was reactivated in the Himalayan orogeny,while the piedmont buried structural belt in the footwall was formed in the Himalayan orogeny.In the footwall of the frontier fault of thrust nappes,the piedmont buried structural belt has good configuration of source rocks,reservoir rocks and cap rocks,presenting good potential to form large gas reservoirs.In comparison,the hanging-wall of the frontier fault of thrust nappes north of Chonghua has poor condition of oil/gas preservation due to the surface exposure of Triassic and deeper strata,while the fault blocks in the hanging-wall from Chonghua to Wudu,with Jurassic cover and thicker gypsum-salt layer of the Jialingjiang formation,has relative better oil/gas preservation conditions and thus potential of oil/gas accumulation.The frontier fault of thrust nappes is not only the boundary between the Longmenshan Mountain and the Sichuan Basin,but also the boundary of the oil/gas accumulation system in northwestern Sichuan Basin.

Geochemical Characteristics and Genetic Types of Natural Gas in the Xinchang Gas Field, Sichuan Basin, SW China

The molecular compositions and stable carbon and hydrogen isotopic compositions of natural gas from the Xinchang gas field in the Sichuan Basin were investigated to determine the genetic types. The natural gas is mainly composed of methane （88.99%-98.01%）, and the dryness coefficient varies between 0.908 and 0.997. The gas generally displays positive alkane carbon and hydrogen isotopic series. The geochemical characteristics and gas-source correlation indicate that the gases stored in the 5th member of the Upper Triassic Xujiahe Formation are coal-type gases which are derived from source rocks in the stratum itself. The gases reservoired in the 4th member of the Xujiahe Formation and Jurassic strata in the Xinchang gas field are also coal-type gases that are derived from source rocks in the 3rd and 4th members of the Xujiahe Formation. The gases reservoired in the 2nd member of the Upper Triassic Xujiahe Formation are mainly coal-type gases with small amounts of oil-type gas that is derived from source rocks in the stratum itself. This is accompanied by a small amount of contribution brought by source rocks in the Upper Triassic Ma＇antang and Xiaotangzi formations. The gases reservoired in the 4th member of the Middle Triassic Leikoupo Formation are oil-type gases and are believed to be derived from the secondary cracking of oil which is most likely to be generated from the Upper Permian source rocks.

Significant progress of continental petroleum geological theory in basins of Central and Western China

China's continental oil and gas geological theory occupies an important academic position in the world's academic circle of petroleum geology. China's oil and gas resources are dominated by continental resources. Chinese geologists have successfully explored and developed complex continental oil and gas, and developed a continental oil and gas geological theory system. This paper summarizes the development history and theoretical achievements of continental oil and gas geological theory since the 1940 s and proposes that the development of this theory should be divided into three stages(i.e., proposal, formation and development). The China's continental oil and gas geological theory has formed a basically perfect theoretical system consisting of five parts, i.e., continental basin structure theory, continental basin sediments and reservoirs theory, continental oil generation theory, continental oil and gas accumulation theory, and continental sandstone oil and gas field development geology. As an advanced geological theory, it has a universal significance globally. This paper focuses on the major discoveries of oil and gas exploration and development and the production growth in the basins of the Central and Western China in the past 30 years as well as the major advances in the continental oil and gas geological theory, including the continental basin tectonics of Central and Western China under the compression background, special reservoir geology such as various types of lake basin sedimentary systems and deep conglomerate, new fields of continental hydrocarbon generation such as coal-generated hydrocarbons, continental oil and gas enrichment regularity such as foreland thrust belts and lithologic-stratigraphic reservoirs, continental unconventional oil and gas geology and continental low-permeability oil and gas development geology. These major advances have greatly developed and enriched the continental oil and gas geological theory and become an important part of it.

Geophysical and Crustal Movement Characteristic of Western Sichuan Basin

Analysis and research of large complex phenomena before and after the devastating earthquake to reduce the threat of natural disasters to human survival environment is of great significance.This paper analyzes the Wenchuan earthquake zone characteristics of gravity anomaly distributions,and then use edge detection and Euler deconvolution method to inverse Longmenshan gravity anomaly before earthquake.Fault distribution features and the general depth about the fault top of Longmenshan and its adjacent area before earthquake has been obtained.Morphology difference and possible earthquake formation have been analyzed through the Euler deconvolution result of gravity anomaly profile before and after the earthquake.

四川盆地川西坳陷东坡地区下侏罗统大安寨段储层裂缝分布预测

四川盆地川西坳陷东坡地区下侏罗统大安寨段是致密油气的主要开发目的层,裂缝是大安寨段储层能否获得高产的关键因素。由于大安寨段地层岩性复杂,传统裂缝预测评价方法适用范围窄、预测结果精度低。基于岩心裂缝调查及薄片鉴定资料,运用地质统计学及数值模拟方法,明确了不同岩性储层的岩石学特征,揭示了大安寨段裂缝发育特征;结合岩石破裂基础和破裂外力二大因素,在区分岩性及亚段的条件下,提出并构建了3项裂缝评价因子,对各亚段裂缝平面分布进行预测评价。研究表明:(1)大安寨段储层为(介壳)灰岩、砂岩及泥页岩相互叠置的复杂岩性;(2)主要发育全充填裂缝,(介壳)灰岩主要发育构造裂缝,砂岩和泥页岩主要发育层间缝,缝面存在溶蚀现象,对油气流动具有积极意义;(3)提出并构建了岩性厚度评价因子、构造变形强度因子和断裂破裂强度因子3项裂缝评价因子,并建立裂缝综合预测评价定量模型,对各亚段裂缝平面分布进行综合预测评价,预测的裂缝密度与单井识别的裂缝发育指数吻合性较好,预测结果可靠。该裂缝平面分布预测评价方法对于同类型油气藏的评价具有借鉴意义。

适应川西地区复杂油气地质条件的物探技术探讨

川西地区以负向构造为主,多期构造演化叠加,断裂发育、储层致密,气水关系复杂,物探采集、成像及储层预测技术适应性较差。概要介绍了分公司在川西地区油气勘探开发历程,总结了随着地质目标变化而形成的物探关键技术及其发展过程,分析了现有采集、处理、解释技术对地质目标的适用性及优缺点,剖析了侏罗系近源薄互层致密砂岩气藏、须家河近源致密气藏以及山前带超深层碳酸盐岩气藏等下一步重点勘探开发目标的研究难点,展望了高精度成像、低频资料储层预测、多尺度断裂系统刻画以及油气水识别等关键物探技术的发展和应用前景,对应用物探前沿技术支撑川西复杂油气区高效勘探开发具有一定的指导意义。

深层致密气地质工程一体化实践——以川西须家河组为例

川西新场—合兴场须家河组天然气资源丰富,中国石化探区保有探明地质储量超1700×10^(8)m^(3),储层具有气藏埋藏深(4500~5500m)、地层压力高(压力系数为1.4~1.7)、地层破裂压力高(110~165MPa)、特低孔隙度(平均孔隙度为3.7%)、特低渗透率(平均渗透率为0.07mD)的“一深两高两低”特点,为天然气成藏地质理论认识及高效开发带来了多重挑战,制约了气藏的勘探开发进程。以地质工程一体化融合实践为攻关思路,深化致密砂岩气输导体成藏认识,明确成藏机理及富集高产规律,以地质甜点发育模式深入解剖为切入点,阐明气藏甜点形成机制,建立甜点地质模式,抓住裂缝和储层地震精细刻画和定量预测技术、优化钻井及储层改造等关键技术,开展地质—地球物理—钻完井关键技术的地质工程一体化协同攻关与技术—经济一体化目标实践,技术序列的成功应用支撑气田规模上产,已累计新建产能超10×10^(8)m^(3),保障合兴场气田新增探明地质储量超1300×10^(8)m^(3),进一步证实了地质工程一体化是低品位气藏有效开发的必经之路,推动了川西须家河组气藏的效益开发进程,为致密难动用储量,特别是深层致密气的勘探开发提供借鉴。

扬子陆块西缘寒武系砂岩的物源分析:对古地理位置重建和构造背景的指示

扬子陆块西缘寒武系主要为一套碎屑岩-碳酸盐岩的岩石组合,前人研究多认为形成于相对稳定的克拉通盆地。但同时期出现的大陆岩浆作用显然与前期认定的克拉通盆地性质不符,需要借助扬子西缘的物质来源探讨构造背景。基于野外露头等资料,本文通过对扬子陆块西缘会泽和会东附近寒武系3件砂岩样品进行重矿物分析、电气石电子探针和碎屑锆石U-Pb测年分析,确定扬子西缘寒武纪沉积物的源区;并结合沉积序列等综合探讨扬子陆块西缘寒武纪的构造背景。沉积序列表明,扬子西缘寒武系沧浪铺组、西王庙组和二道水组主要由砂岩和白云岩等组成,沉积环境为滨岸—潮坪。细—粗砂岩碎屑颗粒为次棱角状—次圆状,分选较差;碎屑组分主要为石英,岩屑几乎全部为燧石,长石含量较少。测试分析结果表明:重矿物分析指示扬子西缘寒武系砂岩重矿物主要由锆石、赤—褐铁矿、电气石、钛铁矿、金红石、磷灰石等组成,重矿物组合指示岩浆岩为其主要母岩;电气石电子探针分析结果表明,物源主要来自于贫锂花岗岩和变砂岩、变泥岩;碎屑锆石测年分析表明物源区母岩主要为983~540 Ma岩浆岩。碎屑锆石年龄对比等综合分析表明,寒武系沉积物部分源自康滇古陆983~708 Ma的岩浆岩和变沉积岩,部分源自冈瓦纳大陆东非造山带663~540 Ma的岩石,物源区岩石经历再旋回产物作用。扬子西缘寒武系的沉积序列、碎屑锆石年龄谱图和碎屑组成等特征综合分析表明,扬子陆块西缘寒武系形成于前陆盆地。

川西地区雷口坡组气藏气源分析与成藏模式

文中以地震、钻井、岩心、气体组分及同位素等资料为基础,分析了川西地区不同构造中三叠统雷口坡组的气藏特征,划分了天然气来源,明确了油气成藏模式。研究表明:根据天然气组分特征差异,可将川西地区雷口坡组气藏划分为烷烃体积分数略低、H2S和CO_(2)等非烃体积分数略高的山前隐伏构造带,以及烷烃体积分数略高、H2S和CO_(2)等非烃体积分数略低的山前坳陷带;根据天然气烷烃同位素特征差异,山前隐伏构造带可划分为δ13C2偏轻、同位素倒序分布的石羊镇、鸭子河构造和δ13C2偏重、同位素正序分布的金马构造;山前坳陷带可划分为δ13C2偏轻、碳同位素值正序分布的新场构造和δ13C2偏重、碳同位素值正序分布的永兴、马井构造。基于天然气运移条件和成藏模式分析认为:石羊镇、鸭子河构造天然气来源于龙潭组和雷口坡组烃源岩;金马、马井构造天然气来源于龙潭组、雷口坡组和马鞍塘组烃源岩;新场构造天然气来源于雷口坡组烃源岩,顶部部分层段由马一段石灰岩供烃;永兴构造天然气来源于马二段页岩。油气成藏模式和断层发育规模是控制川西地区不同构造雷口坡组气藏特征及天然气来源差异的主要因素。

塔里木盆地西北缘乌什西次凹的地层系统和构造特征

乌什西次凹位于塔里木盆地西北缘,隶属于库车坳陷的乌什凹陷。它位于南天山主山脉(哈尔克山)和塔里木盆地柯坪—温宿凸起之间。区域构造格局上,这里是塔里木克拉通向西北自然延伸的部分。次凹北缘的阿合奇断裂是南天山造山带和塔里木克拉通的分界。乌什西次凹内发育与柯坪—温宿凸起相似的晚前寒武纪—古生代地层系统,包括寒武系、奥陶系和石炭系的烃源岩。新近系—第四系碎屑岩建造直接不整合于变形的古生代被动大陆边缘碎屑岩—碳酸盐岩沉积建造之上;剖面上,向南天山方向加厚,向塔里木克拉通方向减薄,呈现典型的前陆盆地剖面结构特征。这是一个晚新生代陆内前陆盆地,叠加在晚海西期—燕山期古隆起之上。这里的构造变形主要有3期,分别是中海西期、晚海西期—印支期和晚喜山期。变形以厚皮冲断构造及其相关褶皱为主,薄皮构造不发育。平面上,主构造线走向NE-SW。剖面上,以南天山向塔里木冲断为主。

四川盆地川中—川西过渡带中侏罗统沙溪庙组致密砂岩相对优质储层成因机制

川中—川西过渡带沙溪庙组天然气勘探潜力巨大,是四川盆地近几年勘探的热点。目前,制约沙溪庙组致密砂岩天然气勘探开发的问题较多,其中,“相对优质储层”的形成机理和综合预测是亟需解决的关键问题之一。针对这一科学问题,本次研究通过系统的物性分析、铸体薄片鉴定、扫描电镜分析以及储层地球化学分析等,开展了研究区沙溪庙组相对优质储层成因机制研究。研究结果表明:沙溪庙组致密砂岩以岩屑长石砂岩和长石岩屑砂岩为主。沙二段砂岩石英平均体积分数为35.27%,长石平均体积分数为35.37%,岩屑平均体积分数为29.36%,沙一段砂岩石英平均体积分数为37.79%,长石平均体积分数为24.01%,岩屑平均体积分数为38.20%,沙一段长石体积分数较高,沙二段岩屑体积分数较高。沙二段以变质岩岩屑为主(占岩屑体积分数的55%),沙一段则以岩浆岩岩屑为主(占岩屑体积分数的43%)。储层孔隙类型以原生孔为主,长石溶蚀孔为辅,沙一段具有相对更高比例的原生孔和裂隙孔。沙二段砂岩中38.00%的样品孔隙度大于12%,25.25%的样品渗透率大于1×10^(-3)μm^(2),沙一段砂岩仅3.09%的样品孔隙度大于12%,但41.22%的样品渗透率大于1×10^(-3)μm^(2)。总体表现为致密背景下发育一定的相对优质储层。其中沙二段储层孔隙度发育较好,而沙一段储层渗透性更佳,说明沙一段储层孔隙结构相对较好。沙溪庙组致密砂岩储层发育受控于岩矿组合-烃源体系-成岩系统。岩矿组合为成岩作用的演化提供物质基础,烃源体系决定溶蚀作用发育的强度,并为砂岩中主要自生矿物的沉淀提供必要的离子来源;成岩系统的开放程度则决定了体系内外离子的带进带出,进而影响了溶蚀作用和相应成岩产物的沉淀。沙二和沙一段砂岩岩矿组合的差异、沉积环境的不同、烃源体系以及成岩系统的开放程度是导致其成岩作用差异的主要原因。综上认为,高能沉积环境、早期保持性成岩作用(孔隙衬垫绿泥石)、多期次和多种类型的溶蚀作用以及局部微裂缝的发育改造,是研究区沙溪庙组相对优质储层发育的主要机制。

四川盆地仪陇—平昌地区侏罗系凉高山组页岩油地质特征及富集条件

基于钻井岩心的地球化学及其他实验分析结果,结合生产测试资料,对四川盆地仪陇—平昌地区侏罗系凉高山组页岩油地质特征及富集条件进行研究,并划分了勘探有利区。研究结果表明:(1)仪陇—平昌地区凉高山组为早侏罗世第3次湖盆扩张期的沉积产物,整体经历了凉下段滨湖—浅湖、凉上段中—下部深湖—半深湖及浅湖、凉上段上部三角洲前缘和浅湖的沉积环境变化。(2)研究区凉高山组页岩可分为长英质页岩、钙质页岩、黏土质页岩等3种;页岩有机质丰度高,TOC值为0.50%~3.39%,平均值为1.30%,有机质类型以Ⅱ_(1)和Ⅱ_(2)型为主,热演化程度高,镜质体反射率(Ro)为1.00%~1.90%,处于高—过成熟阶段。(3)凉高山组页岩物性较好,孔隙度为0.48%~7.17%,平均为3.61%,发育无机成因孔、有机孔和构造缝等储集空间类型;含油性较好,以轻质组分为主,整体呈零散状、点状分布,局部呈团块状富集;凉上段下部富有机质页岩更发育,是目前勘探的重点层位。(4)凉高山组页岩油气的富集受控于前陆盆地过渡期的弱沉降环境、大面积分布的深湖相沉积、较高的热演化程度以及普遍发育的微裂缝。中南部为页岩油气潜力区,页岩储层厚度一般大于15 m,TOC值大于1.50%,孔隙度大于4.00%,R_(o)大于1.30%;凉高山组页岩油资源量为26.75×10^(8)t、页岩气资源量为1.72×10^(12)m^(3),有望成为四川盆地石油产量增加的主力层系。

四川盆地及川西高原地区FY-3D/VASS温湿度廓线检验

利用2020—2021年探空站及ERA5再分析资料,对FY-3D大气垂直探测系统(VASS)温湿度廓线在四川盆地及川西高原地区的精度进行检验。结果表明:与ERA5数据相比,FY-3D/VASS温度在盆地和高原地区不同季节的平均偏差分别为-0.631~0.500℃和-2.230~-1.234℃,均方根误差分别为2.117~3.222℃和3.077~3.460℃,高原比盆地地区大,在垂直高度上,盆地地区的精度在800~700 hPa较低,高原地区的精度随高度的减小逐渐降低;FY-3D/VASS比湿呈现一致的负偏差,平均偏差在盆地和高原地区分别为-0.775~-0.525 g·kg^(-1)和-1.096~-0.347 g·kg^(-1),均方根误差分别为1.251~2.367 g·kg^(-1)和0.696~1.991 g·kg^(-1),在700~600 hPa的精度较低;通过将两组检验的平均偏差相加,间接建立FY-3D/VASS基于探空温湿度数据的检验结果,其中FY-3D/VASS温度在盆地地区的平均偏差较小,高原地区平均偏低2.440℃左右,比湿在盆地和高原地区平均偏低0.612 g·kg^(-1)左右。上述结果可提升FY-3D/VASS温湿度反演产品在四川盆地及川西高原地区的天气气候应用能力。