Evolution of pore systems in low-maturity oil shales during thermal upgrading--Quantified by dynamic SEM and machine learning

In-situ upgrading by heating is feasible for low-maturity shale oil,where the pore space dynamically evolves.We characterize this response for a heated substrate concurrently imaged by SEM.We systematically follow the evolution of pore quantity,size(length,width and cross-sectional area),orientation,shape(aspect ratio,roundness and solidity)and their anisotropy—interpreted by machine learning.Results indicate that heating generates new pores in both organic matter and inorganic minerals.However,the newly formed pores are smaller than the original pores and thus reduce average lengths and widths of the bedding-parallel pore system.Conversely,the average pore lengths and widths are increased in the bedding-perpendicular direction.Besides,heating increases the cross-sectional area of pores in low-maturity oil shales,where this growth tendency fluctuates at<300℃ but becomes steady at>300℃.In addition,the orientation and shape of the newly-formed heating-induced pores follow the habit of the original pores and follow the initial probability distributions of pore orientation and shape.Herein,limited anisotropy is detected in pore direction and shape,indicating similar modes of evolution both bedding-parallel and bedding-normal.We propose a straightforward but robust model to describe evolution of pore system in low-maturity oil shales during heating.

Quantitative effect of kerogen type on the hydrocarbon generation potential of Paleogene lacustrine source rocks,Liaohe Western Depression,China

Kerogen types exert a decisive effect on the onset and capacity of hydrocarbon generation of source rocks.Lacustrine source rocks in the Liaohe Western Depression are characterized by thick deposition,high total organic carbon(TOC)content,various kerogen types,and a wide range of thermal maturity.Consequently,their hydrocarbon generation potential and resource estimation can be misinterpreted.In this study,geochemical tests,numerical analysis,hydrocarbon generation kinetics,and basin modeling were integrated to investigate the differential effects of kerogen types on the hydrocarbon generation potential of lacustrine source rocks.Optimized hydrocarbon generation and expulsion(HGE)models of different kerogen types were established quantitatively upon abundant Rock-Eval/TOC/vitrinite reflectance(R_(o))datasets.Three sets of good-excellent source rocks deposited in the fourth(Es4),third(Es3),and first(Es1)members of Paleogene Shahejie Formation,are predominantly types I-II_(1),II_(1)-II_(2),and II-III,respectively.The activation energy of types I-II_(2)kerogen is concentrated(180-230 kcal/mol),whereas that of type III kerogen is widely distributed(150-280 kcal/mol).The original hydrocarbon generation potentials of types I,II_(1),II_(2),and III kerogens are 790,510,270,and 85 mg/g TOC,respectively.The Ro values of the hydrocarbon generation threshold for type I-III source rocks gradually increase from 0.42%to 0.74%,and Ro values of the hydrocarbon expulsion threshold increase from 0.49%to 0.87%.Types I and II_(1)source rocks are characterized by earlier hydrocarbon generation,more rapid hydrocarbon expulsion,and narrower hydrocarbon generation windows than types II_(2)and III source rocks.The kerogen types also affect the HGE history and resource potential.Three types(conventional,tight,and shale oil/gas)and three levels(realistic,expected,and prospective)of hydrocarbon resources of different members in the Liaohe Western Depression are evaluated.Findings suggest that the Es3 member has considerable conventional and unconventional hydrocarbon resources.This study can quantitatively characterize the hydrocarbon generation potential of source rocks with different kerogen types,and facilitate a quick and accurate assessment of hydrocarbon resources,providing strategies for future oil and gas exploration.

Quantitative characterizations of anisotropic dynamic properties in organic-rich shale with different kerogen content

Understanding the quantitative responses of anisotropic dynamic properties in organic-rich shale with different kerogen content(KC)is of great significance in hydrocarbon exploration and development.Conducting controlled experiments with a single variable is challenging for natural shales due to their high variations in components,diagenesis conditions,or pore fluid.We employed the hot-pressing technique to construct 11 well-controlled artificial shale with varying KC.These artificial shale samples were successive machined into prismatic shape for ultrasonic measurements along different directions.Observations revealed bedding perpendicular P-wave velocities are more sensitive to the increasing KC than bedding paralleling velocities due to the preferential alignments of kerogen.All elastic stiffnesses except C_(13)are generally decreasing with the increasing KC,the variation of C_(1) and C_(33)on kerogen content are more sensitive than those of C_(44)and C_(66).Apparent dynamic mechanical parameters(v and E)were found to have linear correlation with the true ones from complete anisotropic equations independent of KC,which hold value towards the interpretation of well logs consistently across formations,Anisotropic mechanical parameters(ΔE and brittlenessΔB)tend to decrease with the reducing KC,withΔB showing great sensitivity to KC variations.In the range of low KC(<10%),the V_(P)/V_(S) ratio demonstrated a linearly negative correlation with KC,and the V_(P)/V_(S) ratio magnitude of less than 1.75may serve as a significant characterization for highly organic-rich(>10%)shale,compilation of data from natural organic rich-shales globally verified the similar systematic relationships that can be empirically used to predict the fraction of KC in shales.

Extractable and kerogen-bound hopanoids from typical Eocene oil shales in China

This study conducted a comparative analysis of extractable hopanoid hydrocarbons and those released via stepwise pyrolysis of typical Eocene immature oil shales in China,namely the Huadian,Maoming,and Fushun shales.Both the Huadian and Maoming shales exhibit immature indicators in extractable and kerogen-bound hopanoids(notably,high abundance of C_(29)to C_(32)17β,21β-hopanes and unsaturated hopenes).In contrast,the Fushun oil shale's hopanoids from extracts and pyrolyzates suggest a higher maturity level.The absence of neohopenes in the pyrolyzates of the shales underpins that the kerogenbound hopanoid skeletons resist rearrangement.However,the Huadian oil shale's asymmetric distribution of C_(29)and C_(30)hopenes and neohopenes hints at the presence of an additional source.Novel unsaturated hopenes,such as hop-20(21)-enes,identified in pyrolyzates of the three kerogens at various pyrolysis temperatures,reveal the occurrence of double bonds in kerogen-bound hopanoid skeletons without methyl rearrangements.The absence of hop-20-(21)-ene in extracts suggests that it might act as an intermediate of these novel hopenes during the epimerization of hopanoid skeletons within kerogen.The extractable and pyrolytic hopanoids'stereochemical alignment indicates that epimerization may occur in both ring systems and alkyl side chains of kerogen-bound hopanoid skeletons.Sequential stepwise pyrolysis proves to be a quick screening method for geological hopanoids without causing any significant alteration to the original skeletons even when cracking multiple covalent bonds is necessary.

Evolution features of in-situ permeability of low-maturity shale with the increasing temperature,Cretaceous Nenjiang Formation,northern Songliao Basin,NE China

Temperature-triaxial pressure permeability testing at the axial pressure of 8 MPa and confining pressure of 10 MPa,closed shale system pyrolysis experiment by electrical heating and scanning electron microscopy analysis are used to study the evolution mechanism of in-situ permeability in the direction parallel to bedding of low-maturity shale from Member 2(K_(2)n_(2))of Cretaceous Nenjiang Formation in northern Songliao Basin with mainly Type I kerogen under the effect of temperature.With the increasing temperature,the in-situ permeability presents a peak-valley-peak tendency.The lowest value of in-situ permeability occurs at 375℃.Under the same temperature,the in-situ permeability decreases with the increase of pore pressure.The in-situ permeability evolution of low-maturity shale can be divided into 5 stages:(1)From 25℃to 300℃,thermal cracking and dehydration of clay minerals improve the permeability.However,the value of permeability is less than 0.01×10^(-3)μm^(2).(2)From 300℃to 350℃,organic matter pyrolysis and hydrocarbon expulsion result in mineral intergranular pores and micron pore-fractures,these pores and fractures form an interconnected pore network at limited scale,improving the permeability.But the liquid hydrocarbon,with high content of viscous asphaltene,is more difficult to move under stress and more likely to retain in pores,causing slow rise of the permeability.(3)From 350℃to 375℃,pores are formed by organic matter pyrolysis,but the adsorption swelling of liquid hydrocarbon and additional expansion thermal stress constrained by surrounding stress compress the pore-fracture space,making liquid hydrocarbon difficult to expel and permeability reduce rapidly.(4)From 375℃to 450℃,the interconnected pore network between different mineral particles after organic matter conversion,enlarged pores and transformation of clay minerals promote the permeability to increase constantly even under stress constraints.(5)From 450℃to 500℃,the stable pore system and crossed fracture system in different bedding directions significantly enhance the permeability.The organic matter pyrolysis,pore-fracture structure and surrounding stress in the different stages are the key factors affecting the evolution of in-situ permeability.

Distribution and geochemical significance of trace elements in kerogens from Ediacaran–Lower Cambrian strata in South China

Some trace elements(TEs),both bio-essential and redox-sensitive,are promising tracers of Earth’s surface processes.As an essential sedimentary organic matter,kerogen may have inherited and retained the key TEs from organisms.In this study,the distribution of TEs in kerogens from two sections(Dongkanshang and Fengtan) in South China was analyzed to explore its biogeochemical significance during Ediacaran-Lower Cambrian.Compared with V and Zn,the relative concentrations of Co,Ni,Cu,and Mo were generally higher in kerogens than in the whole rocks.Enrichment of TEs in the kerogen was involved in the selective utilization of TEs by different organic precursors and the competition of sulfide in the depositional environment.The significant content of TEs in the kerogens from deep-water facies corresponded to a more negative δ^(13) Ckeras a result of the dominant taxa of chemo autotrophs with tremendous bioaccumulation potential for trace metals and the reduction conditions favorable for organic matter preservation.Furthermore,the content variations of trace elements in the kerogens coincided with the rise and fall of the Ediacaran biota,implying that the trace elements might have played an important role in early life evolution.

Biodegradation of occluded hydrocarbons and kerogen macromolecules of the Permian Lucaogou shales,Junggar Basin,NW China

Three kerogen samples(JJZG-1,JJZG-2 and JJZG-3)isolated from the Permian Lucaogou shales of varying biodegradation levels(BLs≈0,3 and 7,respectively)were subjected to sequential stepwise pyrolysis combined with on-line detection of gas chromatography-mass spectrometry(GC-MS).Occluded fractions(bitumenⅡ)released at low-temperature steps(≥410℃)show consistent biodegradative signatures with that reported for solvent-extracted fractions(bitumenⅠ)of the original shales,e.g.,broad range of abundant n-alkanes,isoprenoids and regular hopanes for the non-biodegraded JJZG-1;trace n-alkanes and abundant hopanes for the moderately biodegraded JJZG-2;and no n-alkanes but still prominent hopanes including the microbially produced 25-nohopanes for the severely biodegraded JJZG-3.This consistency between bitumenⅡand bitumenⅠfractions indicates the biodegradability of the kerogenoccluded bitumenⅡwith limited protection from host kerogen.A minor level of protection was suggested by the trace distribution of n-alkanes in the bitumenⅡof JJZG-2,whereas the bitumenⅠhad no nalkanes.The kerogen itself was more resistant to biodegradation as reflected by the persistence of high abundances of both n-alkanes and hopanes in the high temperature(≥460℃)products of all three kerogen samples.However,the relative abundances of these product groups did show some evidence of biodegradation alteration,e.g.,ratios of n-C_(15)alkene/C_(27)hop-17(21)-ene at 510℃pyrolysis decreased by order of magnitude from the non-biodegraded(JJZG-1=27.4)to highly biodegraded(0.3 for JJZG-3)samples.The reduced biodegradation impact on the kerogen fraction(Cf.bitumen fractions)was also evident by the absence of 25-norhopanes in the high-temperature analysis of the JJZG-3 kerogen.

中国南方高成熟泥页岩有机质微观特征研究

页岩有机质孔隙对页岩气勘探开发有着重要的指示作用,对页岩气生成及运移机理的认知有着重要意义,是研究人员关注的焦点问题。本文采用自然断面制样方法,利用扫描电镜对中国南方高成熟泥页岩进行观察研究发现,有机质主要以三种形态存在于页岩中,一种是细微的颗粒状,微粒尺寸约10~100 nm,与周围矿物界限不明显;一种是呈块状,尺寸多超过10μm,断口表面光滑;一种是部分保留生物形态的有机质,从数量而言以前两种为主。结合有机质成因及特征,作者对其进行分类:第一种为干酪根,第二种为沥青,第三种为生物碎屑。干酪根和沥青中都可能生成孔隙,干酪根内孔隙尺寸较小,形态不规则,沥青中的孔隙尺寸较大,呈气泡状,孔壁较圆滑。因为在泥页岩中干酪根占比比固体沥青多,而且高成熟度的页岩中干酪根中普遍发育孔隙,沥青中较少发育孔隙,所以干酪根孔隙是有机质孔隙的主体。

加强油源岩沉积成岩成油模拟实验研究

干酪根热降解生油学说源于油页岩高温热解生成“人造石油”的生产实践,其理论内涵是凡富含干酪根的岩石,经高温热解后其所含的干酪根都可以生成“人造石油”。应用该学说的高温热解实验方法,可以评价油页岩的品质及其热解生成“人造石油”的潜力,因此仅适用于油页岩的评价研究。但该学说的倡导者却认为油页岩和油源岩都是能生成石油的岩石,如果埋藏较浅时就称为油页岩,如果埋藏较深时就是油源岩,因此干酪根热降解生油学说同样适用于油源岩。这种观点并没有被美欧等国家所认可,但遗憾的是,在改革开放之初不甚了解国外同行对该学说如何评价的情况下,中国的石油地质家不仅全盘接受了该学说,而且推广应用了40多年。为彻底改变这种被动局面,唯一可行的就是通过油源岩沉积成岩成油模拟实验,研究油源岩中可溶有机质的生油问题和评价方法。

干酪根与芳烃化合物固—液有机质相互作用机理研究

地质条件下,烃源岩中最初生成的油气,达到饱和后,才能排出运移,而干酪根对烃类的吸附作用,是影响含油饱和度的重要因素。热解作用产生的烃类物质会与干酪根大分子发生相互作用,研究固体干酪根有机质对液态烃的溶解和吸附能力,可以明确烃源岩对烃类化合物的选择性滞留及生排烃特征。芳烃是石油烃类化合物的重要组成部分,在干酪根三维模型的基础上,利用Autodock软件将不同类型的芳烃化合物分子(包括苯、稠环芳烃和稠环芳烃衍生物)与不同成熟度的干酪根分子进行半柔性对接结算,计算两者结合所需的吉布斯自由能,研究芳烃化合物与干酪根结合的特征,从分子层面上研究干酪根吸附芳烃化合物的机理,揭示固—液有机质相互作用的本质。当与相同成熟度的干酪根结合时,稠环芳烃的分子质量越大、化合物中的甲基数量越多、分子缩合度越高,与干酪根分子结合所需的吉布斯自由能越低;芳烃化合物与干酪根分子之间相互作用受到芳烃的分子质量、分子缩合程度以及体系内甲基数量3个因素的影响。处于生烃高峰后,芳碳甲基含量较高的干酪根对芳烃的吸附能力较强;分子质量大、缩合度高的稠环芳烃及其衍生物与干酪根的结合能力较强;常规连接的小分子芳烃化合物在干酪根中的滞留能力较弱,更易发生排烃作用,运移富集成藏。

古龙油页岩干酪根热解特性分子动力学模拟

古龙页岩油在开发过程中面临油气同出、油品差异大等问题,成烃演化后储层中流体组分组成是影响其有效开发的首要问题。针对上述问题,利用分子动力学模拟建立了古龙油页岩典型的干酪根基质模型,并在此基础上开展了不同温度下的干酪根热解模拟,分析了干酪根热解产物组成以及干酪根基质孔隙结构变化。结果表明:在不同热解温度下,干酪根热解产物中的C1—C5短碳链烃类比例较高,对应着较高的气油比,这与古龙页岩油在实际开发过程中所得到的结果一致;干酪根热解效果随温度的升高而增强,而过高温度反而会抑制干酪根的热解,2500K为最佳热解温度;干酪根热解生成的大量产物堵塞干酪根基质孔隙且伴随着干酪根骨架的坍塌导致基质孔隙度降低,但伴随着后续排烃的进行使得孔隙度大幅上升,从而有利于干酪根热解的进一步开展。研究成果为古龙页岩油的赋存和运移以及实际现场开发中的有效动用提供了理论指导。

松辽盆地古龙页岩油储层干酪根的有机元素组成及其N元素的地球化学意义

对青山口组页岩的317件干酪根样品进行了工业、元素及能谱分析,对样品进行两次校正,引入合理评价干酪根C、H、O、N的指标C_(cc)、H_(cc)、O_(cc)、N_(cc)概念。研究结果显示:古龙凹陷青山口组泥页岩Ⅰ型干酪根具有较高的H_(cc)、N_(cc)和很低的O_(cc),而Ⅲ型干酪根的O_(cc)则较高,H_(cc)、N_(cc)较低。Ⅱ干酪根的H_(cc)和N_(cc)低于Ⅰ型干酪根,而高于Ⅲ型干酪根;Ⅱ干酪根的O_(cc)高于Ⅰ型和Ⅲ型干酪根。N_(cc)主要以有机官能团(NH3+)方式存在的于黏土的F-F纳缝中,而不是存在于黏土晶胞间的无机N(NH4)。微量元素研究表明,古龙青山口组页岩油储层沉积时经历了十几次干旱咸水环境,因为咸水环境有利于形成黏土的F-F凝聚,使发育有NH3+官能团的有机质被吸附在黏土片的F-F纳缝之间。随着深度的增加,N_(cc)的克分子量增加速率是C_(cc)克分子量增加速率的0.96~2.04倍,在青山口组1300~2550m深度内青一段干酪根的N_(cc)含量明显比上部的干酪根相对高,主要原因与下部青一段藻类较富集有关,其次与H_(cc)的快速脱落而使N_(cc)相对富集有关,间接地揭示了青一段生烃能力较上部强。通过研究N_(cc)可以间接地知道古环境中的咸度、黏土的孔隙类型及其干酪根的来源。经过论证,O_(cc)和N_(cc)越大,页岩的封存性也就越好,含油气性也越好。因此,O_(cc)和N_(cc)值可以作为判别页岩油发育程度的指标。古龙页岩油储层的N_(cc)和O_(cc)的研究可以提供一些重要的沉积环境、地球化学、黏土结构、干酪根有机质类型和成岩成储及成藏等信息,应该受到重视。

页岩干酪根平均分子结构模型的构建方法

页岩中的主要有机成分是干酪根。一个真实的干酪根分子结构模型是利用分子动力学研究页岩有机质微观性质的基础。前人多建立二维干酪根模型,对三维干酪根结构模型的建立较少。因此,很有必要介绍一种建立页岩干酪根的三维分子结构模型的详细步骤。笔者等基于构建出的南堡页岩干酪根的二维分子结构模型,利用分子动力学模拟的手段,根据干酪根的密度.

干酪根热解生烃分子模拟研究进展

【意义】干酪根是世界上最丰富的天然有机质来源,研究干酪根的热解对油页岩的开发利用具有重要的意义。传统的热解生烃模拟实验难以深入揭示干酪根热解机理,而分子模拟方法可从原子分子水平上深入揭示干酪根热解的微观机理,是一种重要的研究手段。【进展】对干酪根热解生烃的分子模拟研究进展进行了述评,并结合实验结果,分别阐述了温度、升温速率、水、压力、页岩矿物组分对于干酪根热解的影响。主要有:(1)构建干酪根分子结构模型最常用的方法是基于实验分析方法中获得的元素、官能团信息和结构参数;(2)温度、升温速率、水、压力、页岩矿物组分对干酪根热解产物分子数和组分均存在不同程度的影响,选择合适的温度和升温速率可以使得页岩油的产率达到最大;(3)H2O分子可促进干酪根和重质页岩油的裂解,提高轻质页岩油和气体的产率;(4)对比分子模拟结果与实验结果发现,分子模拟在定量描述方面具有较大的优势,而在定性描述方面稍显不足;(5)分子模拟通常采用提高模拟温度的方法进而缩短反应时间来弥补地质上的热演化时间,这是目前分子模拟技术的缺陷之一;(6)干酪根的高温模拟会产生大量的C2H4,这与实验事实和地质概况不符,也是当前分子模拟的不足之处。【展望】展望未来,干酪根热解生烃分子模拟研究可在以下方面取得发展:(1)使用机器学习法快速构建相对分子量达上百万,并且同时反映干酪根化学结构和孔隙结构的分子结构模型;(2)建立富含页岩矿物组分、地层水、有机酸以及无机盐等多尺度且复杂的干酪根模型;(3)深入研究升温速率、水的相态、地层水、压力、矿物组分以及不同热演化程度对干酪根热解的影响;4)结合实际地质概况探索低温条件下干酪根的热解生烃机制,进而弥补实验—地质—理论之间的鸿沟,为页岩油和页岩气的勘探与开发提供重要的参考信息和理论指导。

中浅层页岩干酪根化学组成与结构特性

中浅层页岩气有20%~85%是吸附气,其主要存在于干酪根中,明晰干酪根的化学结构特性,可为描述页岩气吸附行为,提高页岩气高效开发提供理论依据。本文对中浅层页岩干酪根的化学结构进行表征分析。结果表明:该地区干酪根贫氢富碳,脂肪碳少而芳香碳多;N、S等原子主要以吡咯、噻吩、砜等形式存在。确定了干酪根的分子式为C_(244)H_(108)N_(4)O_(32)S_(5),并模拟构建了干酪根的平均分子结构模型。

Development review and the prospect of oil shale in-situ catalysis conversion technology

As an unconventional resource, oil shale possesses abundant reserves and significant potential for industrial applications. The rational and efficient development of oil shale resources holds immense importance in reducing national energy demand. In-situ catalytic technology, characterized by its high efficiency, low pollution, and minimal energy consumption, represents a key direction for future oil shale development. This paper provides a comprehensive review of research progress in in-situ oil shale mining technology, oil shale pyrolysis catalysts, the pyrolysis mechanism of kerogen, and the compatibility of different heating processes and catalysts. Furthermore, the paper proposes future research directions and prospects for oil shale in-situ catalytic technology, including reservoir modification, highefficiency catalyst synthesis, injection processes, and high-efficiency heating technology. These insights serve as valuable technical references for the advancement of oil shale in-situ catalytic technology.

Geochemical prerequisites for the formation of oil and gas accumulation zones in the South Turgay basin,Kazakhstan

This study predicts favorable oil and gas source-rock formation conditions in the Aryskum Depression of the South Turgay Basin,Kazakhstan.This study assesses the thermal maturity and characteristics of organic matter by determining its environmental conditions using data from geochemical analysis of core(pyrolysis)and oil(biomarkers and carbon isotopic compositions)samples.According to the geochemical parameters obtained by pyrolysis,the oil generation potential of the original rocks of most studied samples varies from poor to rich.The facies–genetic organic matter is predominantly humic and less frequently humus–sapropel,indicating organic matter accumulation in the studied samples were under moderately reducing conditions(kerogenⅢand Ⅱ types)and coastal–marine environments(kerogen typeⅠ).The carbon isotopic compositions of oils derived from the Jurassic deposits of the Aryskum Depression also indicate the sapropelic and mixed humic–sapropelic type of organic matter(kerogenⅡandⅠ).Biomarker analysis of oils indicates original organic matter formation in an anoxic environment.

电磁加热协同纳米颗粒低成熟度陆相页岩油热解实验研究

我国中—低成熟度页岩油储量巨大,是缓解能源供需矛盾的重要非常规资源(郑瑞辉等,2023)。低成熟度页岩油在储层中以固态干酪根形式赋存,目前缺乏高效的开发技术手段。电磁加热不受页岩储层低孔、低渗的影响,能够作用于干酪根将其热解为油气。笔者等以低成熟度陆相页岩为对象并提取干酪根样品,系统开展电磁加热协同纳米催化干酪根热解实验研究.

西湖凹陷Z地区平湖组煤系地层沉积背景及水动力特征

西湖凹陷是中国近海最重要的含油气凹陷之一,在凹陷断陷期末期阶段发育一套巨厚煤系地层,是西湖凹陷主力烃源岩层系,由于受到多解性的影响,很难通过岩性组合、沉积构造等宏观特征详细解释研究区沉积背景及水动力特征,尝试通过煤系地层干酪根显微组分,煤系地层显微岩石学特征等对西湖凹陷Z地区平湖组煤系地层沉积环境及水动力特征展开分析。研究表明,研究区不同地区干酪根显微组分存在较大差异,岩心具有交错纹层状、条带状、水平纹层状、结核状4种形态特征的菱铁矿,均指示Z地区平面及纵向上煤系地层沉积背景及水动力特征存在较大的差异:低凸A区沉积时期以弱氧化-还原沉积环境为主,水浅且间歇性出露水面,其上可发育天然堤与洼地,有利于水道发育;凹陷B区是受外缘低凸起遮挡而形成的半封闭潟湖,整体处于还原沉积背景,在大潮期间,潮流可越过低凸起,将隆起区及隆起区外侧碎屑物搬运至凹陷区而形成冲越扇;低凸C区长期位于水面之上,处于氧化环境,平中段时期受到间歇性潮汐的影响而被水体覆盖,从而形成浅水沼泽;凹陷D区为水体相对较深的沉积背景,是三角洲前缘沉积的有利场所。总体而言,Z地区平湖组沉积环境及水动力特征自南向北受地貌影响存在较大差异:低凸A及C区因长期暴露地表,整体表现为氧化环境,河控为主,间歇性受到潮流影响;凹陷B及D区,整体处于还原沉积环境,受潮汐影响较大。通过对西湖凹陷Z地区沉积背景及水动力特征认识的深化,为该地区勘探部署提供了重要理论支撑。

Molecular Structure of Kerogen in the Longmaxi Shale: Insights from Solid State NMR, FT-IR, XRD and HRTEM

Kerogen plays an important role in shale gas adsorption,desorption and diffusion.Therefore,it is necessary to characterize the molecular structure of kerogen.In this study,four kerogen samples were isolated from the organic-rich shale of the Longmaxi Formation.Raman spectroscopy was used to determine the maturity of these kerogen samples.Highresolution transmission electron microscopy(HRTEM),13 C nuclear magnetic resonance(13 C NMR),X-ray diffraction(XRD)and Fourier transform infrared(FT-IR)spectroscopy were conducted to characterize the molecular structure of the shale samples.The results demonstrate that VReqv of these kerogen samples vary from 2.3%to 2.8%,suggesting that all the kerogen samples are in the dry gas window.The macromolecular carbon skeleton of the Longmaxi Formation kerogen is mainly aromatic(fa’=0.56).In addition,the aromatic structural units are mainly composed of naphthalene(23%),anthracene(23%)and phenanthrene(29%).However,the aliphatic structure of the kerogen macromolecules is relatively low(fal*+falH=0.08),which is presumed to be distributed in the form of methyl and short aliphatic chains at the edge of the aromatic units.The oxygen-containing functional groups in the macromolecules are mainly present in the form of carbonyl groups(fac=0.23)and hydroxyl groups or ether groups(falO=0.13).The crystallite structural parameters of kerogen,including the stacking height(Lc=22.84?),average lateral size(La=29.29?)and interlayer spacing(d002=3.43?),are close to the aromatic structural parameters of anthracite or overmature kerogen.High-resolution transmission electron microscopy reveals that the aromatic structure is well oriented,and more than 65%of the diffractive aromatic layers are concentrated in the main direction.Due to the continuous deep burial,the longer aliphatic chains and oxygen-containing functional groups in the kerogen are substantially depleted.However,the ductility and stacking degree of the aromatic structure increases during thermal evolution.This study provides quantitative information on the molecular structure of kerogen samples based on multiple research methods,which may contribute to an improved understanding of the organic pores in black shale.