Differences and identification on multi-time hydrocarbon generation of carboniferous-permian coaly source rocks in the Huanghua Depression,Bohai Bay Basin

Coal is a solid combustible mineral,and coal-bearing strata have important hydrocarbon generation potential and contribute to more than 12%of the global hydrocarbon resources.However,the deposition and hydrocarbon evolution process of ancient coal-bearing strata is characterized by multiple geological times,leading to obvious distinctions in their hydrocarbon generation potential,geological processes,and production,which affect the evaluation and exploration of hydrocarbon resources derived from coaly source rocks worldwide.This study aimed to identify the differences on oil-generated parent macerals and the production of oil generated from different coaly source rocks and through different oil generation processes.Integrating with the analysis of previous tectonic burial history and hydrocarbon generation history,high-temperature and high-pressure thermal simulation experiments,organic geochemistry,and organic petrology were performed on the Carboniferous-Permian(C-P)coaly source rocks in the Huanghua Depression,Bohai Bay Basin.The oil-generated parent macerals of coal's secondary oil generation process(SOGP)were mainly hydrogen-rich collotelinite,collodetrinite,sporinite,and cutinite,while the oil-generated parent macerals of tertiary oil generation process(TOGP)were the remaining small amount of hydrogen-rich collotelinite,sporinite,and cutinite,as well as dispersed soluble organic matter and unexhausted residual hydrocarbons.Compared with coal,the oil-generated parent macerals of coaly shale SOGP were mostly sporinite and cutinite.And part of hydrogen-poor vitrinite,lacking hydrocarbon-rich macerals,and macerals of the TOGP,in addition to some remaining cutinite and a small amount of crude oil and bitumen from SOGP contributed to the oil yield.The results indicated that the changes in oil yield had a good junction between SOGP and TOGP,both coal and coaly shale had higher SOGP aborted oil yield than TOGP starting yield,and coaly shale TOGP peak oil yield was lower than SOGP peak oil yield.There were significant differences in saturated hydrocarbon and aromatic parameters in coal and coaly shale.Coal SOGP was characterized by a lower Ts/Tm and C31-homohopane22S/(22S+22R)and a higher Pr/n C17compared to coal TOGP,while the aromatic parameter methyl dibenzothiophene ratio(MDR)exhibited coaly shale TOGP was higher than coaly shale SOGP than coaly TOGP than coaly SOGP,and coal trimethylnaphthalene ratio(TNR)was lower than coaly shale TNR.Thus,we established oil generation processes and discriminative plates.In this way,we distinguished the differences between oil generation parent maceral,oil generation time,and oil production of coaly source rocks,and therefore,we provided important support for the evaluation,prediction,and exploration of oil resources from global ancient coaly source rocks.

Identification of the lower limit of high-quality source rocks and its relation to hydrocarbon accumulation——Taking the Beier Sag in the Hailaer Basin as an example

The theory of ＂source rock control＂ has evolved from source-rock-control hydrocarbon accumulation, to effective source-rock-control hydrocarbon accumulation, and to high-quality source- rock-control hydrocarbon accumulation. However, there are problems, such as whether high-quality source rocks exist or not？ What high-quality source rocks are, and how to identify them, are yet to be agreed upon. Aimed at this issue of concern to explorationists, and taking the Beier Sag in the Hailaer Basin as an example, this paper defines the high-quality source rocks and the lower limit for evaluation of high-quality source rocks, by using the inflection point on the relationship curve of hydrocarbon （oil） expulsion, which is calculated by the material balance principle, versus total organic carbon （TOC）. The results show that when TOC is low, all source rocks have limited hydrocarbon expulsion and slow growth rate, thus they cannot be high-quality source rocks. However, when TOC rises to some threshold, hydrocarbon expulsion increases significantly with TOC. This inflection point should be the lower limit of high-quality source rocks： those with TOC greater than the inflection-point value are high-quality source rocks. In addition, the lower limit of high-quality source rocks is also related to the type and maturity of organic matters in the source rocks, as well as the mineral components of the source rocks affecting the residual hydrocarbons. Theoretically, the lower limit of high-quality source rocks depends on geological conditions rather than being a constant value. However, for the sake of simplicity and practicability, in this paper TOC=2.0% is regarded as the lower limit of high-quality source rocks. The examination of such standard in the work area indicates that the high-quality source rocks in members K^n2 and K^n~ of the Nantun formation contribute 76% and 82% to oil generation, and 96% and 91% to oil expulsion, respectively. The distribution of high-quality source rocks is also closely related to the distribution of hydrocarbon reservoirs in the region, demonstrating that high-quality source rocks control hydrocarbon accumulation.

“Exploring petroleum inside source kitchen”: Connotation and prospects of source rock oil and gas

Based on the transitional background of the global energy structure, exploration and development of unconventional oil and gas, and investigation of key basins, the unconventional oil and gas resources are divided into three types: source rock oil and gas, tight oil and gas, and retention and accumulated oil and gas. Source rock oil and gas resources are the global strategic supplies of oil and gas, the key resource components in the second 150-year life cycle of the future petroleum industry, and the primary targets for "exploring petroleum inside source kitchen". The geological connotation of source rock oil and gas was proposed, and the models of source rock oil and gas generation, expulsion and accumulation were built, and five source rock oil and gas generation sections were identified, which may determine the actual resource potential under available technical conditions. The formation mechanism of the "sweet sections" was investigated, that is, shale oil is mainly accumulated in the shale section that is close to the oil generation section and has higher porosity and permeability, while the "sweet sections" of coal-bed methane(CBM) and shale gas have self-contained source and reservoir and they are absorbed in coal seams or retained in the organic-rich black shale section, so evaluation and selection of good "sweet areas(sections)" is the key to "exploring petroleum inside source kitchen". Source rock oil and gas resources have a great potential and will experience a substantial growth for over ten world-class large "coexistence basins" of conventional-unconventional oil and gas in the future following North America, and also will be the primary contributor to oil stable development and the growth point of natural gas production in China, with expected contribution of 15% and 30% to oil and gas, respectively, in 2030. Challenges in source rock oil and gas development should be paid more attention to, theoretical innovation is strongly recommended, and a development pilot zone can be established to strengthen technology and promote national support. The source rock oil and gas geology is the latest progress of the "source control theory" at the stage of unconventional oil and gas. It will provide a new theoretical basis for the new journey of the upstream business in the post-industry age.

Genesis and distribution of oils in Mahu Sag,Junggar Basin,NW China

Based on the geological and geochemical analysis of potential source rocks in different formations and the classification of crude oil types,combined with the hydrocarbon generation thermal simulation experiments,the source,genesis,and distribution of different types of oils in the Mahu large oil province of the Junggar Basin are investigated.Four sets of potential source rocks are developed in the Mahu Sag.Specifically,the source rocks of the Permian Fengcheng Formation have the highest hydrocarbon generation potential and contain mainly TypesⅡandⅠorganic matters,with a high oil generation capacity.In contrast,the source rocks in other formations exhibit lower hydrocarbon generation potential and contain mainly TypeⅢorganic matter,with dominant gas generation.Oils in the Mahu Sag can be classified as three types:A,B and C,which display ascending,mountainous and descending C_(20)-C_(21)-C_(23)tricyclic terpenes abundance patterns in sequence,and gradually increasing relative content of tricyclic terpenes and sterane isomerization parameters,indicating an increasing oil maturity.Different types of oils are distributed spatially in an obviously orderly manner:Type A oil is close to the edge of the sag,Type C oil is concentrated in the center of the sag,and Type B oil lies in the slope area between Type A and Type C.The results of oil-source correlation and thermal simulation experiments show that the three types of oils come from the source rocks of the Fengcheng Formation at different thermal evolution stages.This new understanding of the differential genesis of oils in the Mahu Sag reasonably explains the source,distribution,and genetic mechanism of the three types of oils.The study results are of important guidance for the comprehensive and three-dimensional oil exploration,the identification of oil distribution in the total petroleum system,and the prediction of favorable exploration areas in the Mahu Sag.

Hydrocarbon Systems in the North-Eastern Area of the Song Hong Basin

This paper reports some results of geo-scientific evaluation of the petroleum systems in the northeastern area of the Song Hong Basin offshore Vietnam. Geological-geophysical data, including regional studies, 2D and 3D seismic ＆ logging interpretation results as well as core/cutting samples analysis were integrated to reveals that the north-eastern area were controlled by pull apart activities along Song Hong river fault system, rifting phase during Eocene-Oligocene and subsidence during Miocene-Quaternary. Inversion activities at the end of Oligocene and late Miocene also play very important roles. These activities convert Pre-tertiary carbonate basement rocks to be potential reservoirs. The main source rock, overlying and adjacent to basement highs, was deposited in the lacustrine environment during rifting phase of Eocene and Oligocene and is still at the depth of oil generation window. The mentioned source rock layer is also considered as a good top seal for the basement. Petroleum system has been proven by the drilling and testing results and the studied area become more attractive and have higher chance of success.

油气地质勘探将从烃源岩时代进入幔源油气新时代

简要梳理了人类石油勘探发展历程,分析并研究了国内外25个油田(或盆地、油区)的勘探资料,得出结论:石油地质勘探经历过的第一个阶段是背斜(构造)勘探阶段(19世纪60年代~20世纪60年代),第二个阶段是烃源岩勘探阶段(20世纪30年代至今),现在已经进入一个全新的阶段——幔源油气勘探时代。依据幔源油气理论,提出了创新的“盆-壳-幔镜像叠置成藏模式”。

“源热共控”中国近海盆地油气田“内油外气”有序分布

源热共控油气形成,烃源岩是油气形成的内因,热是油气形成的外因,内因和外因缺一不可,二者耦合作用控制了含油气区内油气的形成、资源潜力与分布模式。中国近海沉积盆地主要属于新生代伸展盆地或张扭盆地,古近纪发生裂陷,早—中中新世发生区域性热沉降,晚中新世以来新构造活动在多数盆地比较活跃。中国近海新生代盆地烃源岩主要形成于古近纪裂陷期断陷,根据沉积充填特征分为陆相断陷和叠合断陷,陆相断陷指断陷期地层完全为陆相地层充填的凹陷,叠合断陷指除陆相地层充填外,还存在海相或海陆过渡相地层充填的断陷。渤海海域、黄海海域、珠江口盆地北部坳陷带和北部湾盆地古近纪断陷都属于陆相断陷,处于克拉通内部或大陆架,称为内带;东海盆地、台西盆地、台西南盆地、珠江口盆地南部坳陷带、琼东南盆地及莺歌海盆地的古近纪断陷都属于叠合断陷,处在活动大陆边缘或被动大陆边缘陆坡区,称为外带。内带陆相断陷主要烃源岩为中深湖相源岩,分布时代包括古新世、始新世和渐新世,以始新世为主;外带叠合断陷烃源岩包括湖相烃源岩、海陆过渡相烃源岩和海相烃源岩,其中以海陆过渡相烃源岩为主,分布时代包括古新世、始新世、渐新世,以始新世—渐新世为主。内带湖相烃源岩倾向生油,外带海陆过渡相和海相烃源岩倾向生气。近海盆地内带热流值低—较高,外带热流值高—超高。烃源岩与热场耦合,内带倾油型烃源岩在相对较低的温度场作用下主要生油,外带倾气型烃源岩在较高的温度场作用下主要生气。因此,近海内带主要生油是找油的领域,外带主要生气是找天然气领域。中国近海石油的主要勘探领域在内带的渤海、南海北部北带和南黄海海域断陷,天然气主要勘探领域在外带的南海北部陆坡及东海海域。

“进源找油”:源岩油气内涵与前景

基于全球能源结构转型背景、非常规油气勘探开发进展和重点盆地研究对比分析,将非常规油气划分为源岩油气、致密油气和滞聚油气3种类型,明确源岩油气是全球油气供应的战略领域,是未来石油工业第2个150 a生命周期中举足轻重的资源组成,是"进源找油"的主要对象。提出源岩油气地质学内涵,集成建立了源岩油气生、排、滞留烃模式,指出5个源岩油气生成段决定相应技术条件下的现实资源潜力;分析了源岩油气"甜点段"形成机理,发现页岩油主要聚集在紧贴生油段、孔渗较好的泥页岩段,而煤层气和页岩气"甜点段"源储一体、吸附在煤层表面或滞留在富有机质黑色页岩段,评价优选源岩油气"甜点区(段)"是"进源找油"的核心;源岩油气资源潜力巨大,继北美之后,全球十余个大型常规-非常规"共生盆地"源岩油气也将迎来大发展,源岩油气是中国未来石油稳定发展的主力、天然气产量跨越的增长点,预计2030年中国源岩油和源岩气产量将分别占比15%和30%;应对源岩油气发展挑战,建议坚持理论创新、设立开发试验区、加强技术攻关、争取国家支持等。源岩油气地质,是"源控论"在非常规油气阶段的新发展,将为承续和推进后油气工业时代上游领域新征程提供新的理论依据。

鄂尔多斯盆地定边庆阳地区长7段致密油烃源岩地质数据挖掘与评价

探讨鄂尔多斯盆地上三叠统长7段致密油有效烃源岩的主控地质因素及分布特征。结合地质异常理论,采用因子分析、痕量元素分析、趋势面分析及标准化处理等技术手段,提出一种对研究区长7段烃源岩进行地质数据挖掘与信息整合的评价方法,建立表征烃源岩品质的综合性无因次线性组合,揭示出在有机碳丰度普遍较高的背景下,有效烃源岩的发育主要受控于低等水生生物勃发(有机质类型指数)与有机质热演化程度(镜质体反射率)。有效烃源岩集中分布于姬塬南部、定边西部、油房庄东部、华池地区及合水东北部,对致密油高产富集带的分布具有一定的控制作用。有利于进一步提高长7段致密油勘探开发成效的地区主要是耿湾-环县、华池北部、油房庄-吴仓堡及定边。

“未熟油”与“未熟生烃”异议

有关专家认为,“未熟生烃”是我国新生代盆地广泛存在的地球化学现象。本文剖析了这一论点背后隐含的矛盾,并以苏北盆地部分断陷中存在的“不等深等温”、“不等深等熟”、成熟度指标与埋深关系的“平行变浅”分布等资料为依据,提出此现象当源于“古大于今”埋深史这一特定地质背景(或称为退化型受热史)。若以恢复的最大古埋深重新勾画产烃率曲线,所谓“低温早熟”现象即可消除。既然未熟生烃现象不存在,也就不存在未熟的石油。同时指出,对此类盆地的后期抬升幅度及其不均衡性估计不足是产生这一认识的主要根源。

用逻辑思维重建中国陆相生油理论

中国陆相生油是我国老一代石油地质家提出的,它不仅有效指导了中国陆相沉积盆地的石油勘探,也为中国陆相生油理论研究提供了丰富资料和宝贵经验。中国的石油地质家本应继承老一辈的优良学风,坚持通过石油勘探实践研究中国陆相石油地质理论。但1978年干酪根热降解生油学说引入我国之后,我国一些石油地质家在迷信崇拜外国知名学者和急于求成的思想影响下,在没有完全理解该学说理论内涵的情况下,就全盘接受该学说并在我国全面推广应用,从此把中国陆相生油理论研究引入误区。干酪根热降解生油学说既不研究烃源岩的形成与演化,也不研究烃源岩的生油条件和某演化阶段的实际生油量,只研究烃源岩中所含的干酪根在温度作用下的生烃潜量,因此该学说只是用有机地球化学思维研究温度与石油生成关系的一种实验方法,不是烃源岩生油理论。必须抛弃模仿思维,运用逻辑思维重建中国陆相生油理论研究思路和方法 ,重点针对生油凹陷(或洼陷)即"深坳陷"沉积发育史和烃源岩岩性组合划分,烃源岩有机质热演化条件和环境,烃源岩内油、气、水三相态流体赋存特征展开研究。

从传统理论体系到创新理论思维——以含油气盆地研究和烃源岩生烃理论为例

创新理论思维是产生创新理论的基础和前提,而创新理论是相对传统理论体系而言的,创新理论的形成其实就是从传统理论体系到创新理论思维的研究过程。例如目前在含油气盆地研究方面有两种思维方法:一种是传统大地构造理论体系,其研究内容主要是形态描述和成因分析,沉积盆地与油气富集的关系则主要通过含油气盆地类型与油气富集程度之间的统计数据来说明,这既误导了油气勘探的目标和方向,也误导了含油气盆地的研究方向;另一种是石油地质理论思维方法,它认为一个沉积盆地能否成为含油气盆地以及油气是否丰富,主要取决于盆地整体沉降阶段能否沉积完整的生、储、盖层及上覆岩层,特别是能否发育一套优质烃源岩并经热演化实现成烃过程,含油气盆地的研究内容主要是盆地发育史和石油地质演化史。在烃源岩生烃理论研究方面也有两种不同的思维方法:一种是干酪根热降解晚期生烃学说,它实际上是油页岩热解生成页岩油的翻版,其热降解模拟结果存在明显的理论脱离实际的问题,以生油岩的生油潜量代替实际生油量,导致用成因法计算的石油资源量存在概念性错误;针对该学说存在的问题,提出了烃源岩有限空间生烃理论思维的新概念,烃源岩在成岩演化和有机物热演化过程中,提供有机物热降解反应以及容纳生成石油的只能是烃源岩此阶段的孔隙空间,它是有限的,而且随着埋深的增加而减小。

如何重建中国陆相烃源岩生油理论

欧洲有机化学家在多年研究和实验的基础上,提出了干酪根热降解生油学说,而后又将其上升为烃源岩热降解生油学说,即烃源岩生油理论。实际上该学说是用有机化学的思维方法和实验技术,研究干酪根在高温作用下的生油过程和特点。但烃源岩生油问题是研究烃源岩在地质条件下的生油过程和特点,是有机地球化学研究的课题。对有机化学而言,化学反应的三个基本条件都是人为因素完成的,即都是可知的;但对有机地球化学来讲,这三个基本条件是不可知的,只能通过勘探手段和石油地质综合研究、模拟实验等方法获知。用有机化学的思维方法研究烃源岩生油问题时,无需对烃源岩和生油凹陷(或洼陷)做石油地质条件的综合分析研究;而采用有机地球化学的思维方法,首先要了解烃源岩的物质成分特征和生油凹陷(或洼陷)的石油地质条件,才能研制烃源岩生油模拟仪并开展模拟实验,在石油地质综合分析及模拟实验的基础上,才能开展烃源岩生油评价研究。重建中国陆相烃源岩生油理论的思维方法,是在对含油气盆地在整体持续沉降阶段有机物富集、向油气转化以及生成油气与孔隙水之间的互溶和保存进行研究的基础上,开展相关的模拟实验,最终完成重建研究。主要内容包括全国主要含油气盆地的石油地质特征研究、主力烃源岩全岩分析研究,以及烃源岩生油模拟实验仪的研制及相关单因素物质的模拟实验研究。

干酪根热降解生油学说是“人造石油”理论

自1978年干酪根热降解生油学说引入我国以来,在长达40多年的时间里,我国陆相油源岩理论研究及石油勘探和高校教学领域,一直都应用该学说的理论和高温热解实验技术,至今在我国有机地球化学界仍占据主导地位。殊不知,该学说仅是适用于油页岩热解生成“人造石油”的理论和相配套的高温热解实验。实质是把油源岩等同于油页岩,认为两者都是能大量生成石油的岩石,唯一不同的是埋藏深度的差异,因此就可以把油页岩的评价方法,全部用于油源岩的研究和石油勘探中。适用于油页岩生油潜力研究的干酪根热降解生油学说,就成为了油源岩热降解生油学说。这种推理性思维方法是把油页岩和油源岩,均放在有机化学的平台上进行对比分析研究,回避了油源岩的生油是有机地球化学问题,把二者混为一谈,是在用评价油页岩生成“人造石油”的理论和实验方法,去研究天然石油油源岩的生油理论问题。由此培养的诸多人才,都是用“人造石油”理论和实验方法研究天然石油的有机化学家。在地下地质条件下油源岩所含的干酪根是不能热解生油的,真正能对生油和形成油藏有贡献的是油源岩所含的可溶有机质。油源岩所含的可溶有机质的形成及演化特征,才是油源岩生油理论研究的核心内容。

“源热共控”中国油气田有序分布

以油气区(盆地群)为单元,基于"源热共控论",分析了中国大陆及海域油气田纵向成烃规律。结果表明,我国油气田的油气成烃模式非常有序:①东南部海域油气区包括东海和南海的盆地,纵向上呈单相成烃模式,源热共控生油或者生气,其中近岸带以油为主,远岸带以气为主;②东部油气区包括渤海湾盆地—松辽盆地—江汉盆地带、北黄海—南黄海盆地,成烃呈"上油下气"双层模式;③中部油气区包括鄂尔多斯盆地—四川盆地—楚雄盆地带,成烃呈"上油下气"双层模式;④西部油气区包括准噶尔盆地、塔里木盆地、吐哈盆地和柴达木盆地等,成烃呈"三明治"式多层模式。结论认为:①"源热共控"中国油气勘探的重大领域;②找油领域为东南海域的近岸带,东部油气区的上部层系,中部油气区的上部层系,西部油气区的奥陶系、二叠系和古近系;③找气领域为东南海域的远岸带,东部油气区的中深层,中部油气区中深层,西部油气区的寒武系、石炭系、侏罗系和第四系等多个层系;④呈现出油田下面找气田、气田底下找油田、油田外面找气田、气田外面找油田的格局;⑤我国油气勘探领域依然广阔。

“源热共控”澳大利亚西北大陆边缘油气田有序分布

澳大利亚西北大陆边缘是全球油气最富集的区域之一,研究其油气分布规律及主控因素有助于指导下一步的油气勘探。为此,基于8个沉积盆地近60年的勘探成果资料,分析了各盆地的油气地质条件和油气分布特征,发现该区油气田呈"近岸油""远岸气"有序分布,指出这一分布模式主要是受烃源岩和热演化程度的共同控制。进一步依据"源热共控"论,深入探讨了烃源岩的成烃规律和成烃模式,并指出了下一步的勘探方向。结论认为:①北卡纳文盆地发育3套烃源岩,即中—上三叠统海陆过渡相三角洲泥岩、下—中侏罗统海相/海陆过渡相三角洲泥岩和上侏罗统—下白垩统海相泥岩,而布劳斯和波拿巴盆地主要发育2套烃源岩,即下—中侏罗统海相/海陆过渡相三角洲泥岩和上侏罗统—下白垩统海相泥岩;②该区大地热流值从近岸带向远岸带增大,局部存在异常,烃源岩热演化程度随埋深增大而增高;③从近岸带向远岸带,有机质存在从生油向生气转化的趋势,未来找油的主要领域应在近岸带,找气的主要领域在远岸带,该区天然气资源潜力巨大。

Reservoir forming conditions and key exploration technologies of Lingshui 17-2 giant gas field in deepwater area of Qiongdongnan Basin

On September 15,2014,China National Offshore Oil Co.,Ltd announced that a high production of oil and gas flow of 1.6
106 m3/d was obtained in Well LS17-2-1 in deepwater area in northern South China Sea,which is the first great oil and gas discovery for self-run deepwater exploration in China sea areas,and a strategic breakthrough was made in natural gas exploration in deepwater area of Lingshui sag in Qiongdongnan Basin.Under the combined action of climax of international deepwater exploration,high oil prices,national demands of China,practical needs of exploration,breakthroughs in seismic exploration and testing technologies,innovations in geological cognition and breakthroughs in deepwater operation equipment,Lingshui 17-2 gas field is discovered.Among these factors,the innovation in reservoir forming geological cognition directly promotes the discovery.The quality of seismic data in the early time is poor,so key reservoir forming conditions such as effective source rocks,high quality reservoirs and oil-gas migration pathways are unable to be ascertained;with support of new seismic acquisition and processing technology,some researches show that Lingshui sag is a successive large and deep sag with an area of 5000 km2 and the maximum thickness of Cenozoic stratum of 13 km.In the Early Oligocene,the Lingshui sag was a semi-closed delta-estuarine environment,where the coalmeasure and marine mudstones in Lower Oligocene Yacheng Formation were developed.The Lingshui sag is a sag with high temperature,and the bottom temperature of source rocks in Yacheng Formation can exceed 250C,but the simulation experiment of hydrocarbon generation at high temperature indicates that the main part of this set of source rock is still in the gas-generation window,with resources of nearly 1 trillion cubic meters,so the Lingshui sag is a hydrocarbon-rich generation sag.In the Neogene,the axial canyon channel from the Thu Bon River in Vietnam passed through the Lingshui sag,and five stages of secondary channels were developed in the axial canyon channel,where four types of reservoirs with excellent physical properties including the axial sand,lateral accretion sand,natural levee sand as well as erosion residual sand were developed,and lithologic traps or structural-lithologic traps were formed.The diapiric zone in the southern Lingshui sag connects deep source rocks in Yacheng Formation and shallow sandstones in the channels,and the migration pattern of natural gas is a T-type migration pattern,in other words,the natural gas generated from Yacheng Formation migrates vertically to the interior of the channel sandbody,and then migrates laterally in the channel reservoirs and forms the reservoirs.Innovations of geophysical exploration technologies for complicated geological conditions of deepwater areas are made,such as the detuning comprehensive quantitative amplitude hydrocarbon detection technology,which greatly improves the success rate of deepwater exploration;key technologies of deepwater safety exploratory well testing represented by the platform-dragged riser displacement technology are developed,which greatly reduces the drilling test cost.The above key exploration technologies provide a strong guarantee for the efficient exploration and development of Lingshui gas field.