共查询到19条相似文献,搜索用时 234 毫秒
1.
ZHOU Wen ZHAO Guanjun LIU Fei YE Bin LI Xiuhu HUANG Tingting ZHOU Qiumei DONG Guoliang 《《地质学报》英文版》2011,85(19):899-910
The ancient structure characteristic, correlation of the oil and the hydrocarbon source rock characteristics, hydrocarbon migration trace, types and conditions of traps, migration passages and characteristic of hydrocarbon accumulation are researched in this paper. It is shown through the analysis that two main large tectonic activities after the Early Hercynian orogeny resulted in different tectonic patterns in the study area. Two main hydrocarbon infills occurred in the Donghetang Formation, the first occurred in the Early Hercynian resulting in the ancient hydrocarbon accumulation in the northern Tahe, the second infill was a large amount that occurred in places beneficial for hydrocarbon accumulation, such as structural traps and structural-stratigraphic traps formed in the Early Himalayan orogeny after migration along the faults through source rocks and other passages. Before the earlier period of the Himalayan orogeny, the petroleum mainly migrated to the north, whereas petroleum migrated to the south and southeast because of the structural reverse in the Himalayan orogeny, so the middle and later period of the Himalayan orogeny is the key period for hydrocarbon accumulation. The model of “oil generation formed early, hydrocarbon accumulation controlled by the faults through source rocks and structures formed late” is proposed. It is pointed out that the south of the research area is currently the beneficial district for hydrocarbon accumulation, which provides the basis for future petroleum exploration. 相似文献
2.
The paper systematically analyzes the hydrocarbon migration characteristics of the Lower Cretaceous in the Erlian Basin, based on the geochemical data of mudstone and sandstone in the main hydrocarbon-generating sags. (1) The source rocks in K1ba and K1bt1 are estimated to be the mature ones, their hydrocarbon expulsion ratio can reach 32%-72%. The Type-I sags in oil windows possess good hydrocarbon generation and expulsion conditions, where commercial reservoirs can be formed. (2) According to the curves of the mudstone compaction and evolution of clay minerals, the rapid compaction stage of mudstones is the right time of hydrocarbon expulsion, i.e., primary migration. (3) The timing between hydrocarbon generation and expulsion is mainly related to the accordance of the oil window and the rapid compaction stage of mudstones in the hydrocarbon generation sags of Type-I. That forms the most matching relation between hydrocarbon generation and migration. (4) The faults and unconformities are the important paths for the secondary hydrocarbon migration. Especially, the unconformity between K1ba and K1bt1 has a favorable condition for oil accumulation, where the traps of all types are the main exploration targets. (5) Hydrocarbon migration effect, in the Uliastai sag, is most significant; that in the Saihan Tal and Anan sags comes next, and that in the Bayandanan and Jargalangt sags is worst. 相似文献
3.
It is concluded that there are three hydrocarbon generation and accumulation processes in northeastern Sichuan on the basis of the characteristics of solid bitumen, gas-light oils-heavy oils, homogenization temperature of fluid inclusions and diagenesis for beach- and reef-facies dolomite gas- bearing reservoirs in the Puguang Gas Field, northeastern Sichuan Basin, southern China. The first hydrocarbon generation and accumulation episode occurred in the Indosinian movement (late Middle Triassic). The sapropelic source rocks of the O3w (Upper Ordovician Wufeng Formation)-S1l (Lower Silurian Longmaxi Formation) were buried at depths of 2500 m to 3000 m with the paleogeothermal temperature ranging from 70℃ to 95℃, which yielded heavy oil with lower maturity. At the same time, intercrystalline pores, framework pores and corrosion caused by organic acid were formed within the organic reef facies of P2ch (Upper Permian Changxing Formation). And the first stage of hydrocarbon reservoir occurred, the level of surface porosity of residual solid bitumen {solid bitumen/ (solid bitumen + residual porosity)} was higher than 60%. The second episode occurred during the Middle Yanshanian movement (late Middle Jurassic). During that period, the mixed organic source rocks were deposited in an intra-platform sag during the Permian and sapropelic source rocks of O3w-S1l experienced a peak stage of crude oil or light oil and gas generation because they were buried at depths of 3500 m to 6800 m with paleogeothermal temperatures of 96-168℃. At that time, the level of surface porosity of residual solid bitumen of the T1f shoal facies reservoirs was between 25% and 35%, and the homogenization temperatures of the first and second stages of fluid inclusions varied from 100℃ to 150℃. The third episode occurred during the Late Yanshanian (Late Cretaceous) to the Himalayan movement. The hydrocarbon reservoirs formed during the T1f and P2ch had the deepest burial of 7700 m to 8700 m and paleogeotemperatu 相似文献
4.
By analyzing the characteristics of development, structural evolution and reservoir beds of the residual carbonate strata, this study shows that the residual carbonate strata in the Yingmaili low uplift are favorable oil and gas accumulation series in the Tabei (northern Tarim uplift) uplift. There are different patterns of hydrocarbon accumulation on the northern and southern slopes of the Yingmaili low uplift. The north-south differentiation of oil reservoirs were caused by different lithologies of the residual carbonate strata and the key constraints on the development of the reservoir beds. The Mesozoic terrestrial organic matter in the Kuqa depression and the Palaeozoic marine organic matter in the Manjiaer sag of the Northern depression are the major hydrocarbon source rocks for the northern slope and southern slope respectively. The hydrocarbon accumulation on the northern and southern slopes is controlled by differences in maturity and thermal evolution history of these two kinds of organic matter. On the southern slope, the oil accumulation formed in the early stage was destroyed completely, and the period from the late Hercynian to the Himalayian is the most important time for hydrocarbon accumulation. However, the time of hydrocarbon accumulation on the northern slope began 5 Ma B.P. Carbonate inner buried anticlines reservoirs are present on the southern slope, while weathered crust and paleo-buried hill karst carbonate reservoirs are present on the northern slope. The northern and southern slopes had different controlling factors of hydrocarbon accumulation respectively. Fracture growth in the reservoir beds is the most important controlling factor on the southern slope; while hydrocarbon accumulation on the northern slope is controlled by weathered crust and cap rock. 相似文献
5.
In the Yongjin oilfield of southern Junggar Basin, many wells have been drilled to produce industrial oils. Based on the analysis of fluid inclusions in the reservoirs, in combination with the geological and thermal evolution, the charge history in this area has been studied. The results indicate that the Jurassic Formation and Cretaceous Formation reservoirs contain abundant oil and gas inclusions, and four types of fluid inclusions have been distinguished. According to the homogenization temperatures of the fluid inclusions, the hydrocarbons charged the Cretaceous Formation for two periods, one ranges from the Late Cretaceous period to the Eogene period, and the other ranges from the Neocene period to the present. The oil filling history is correlated with the oil source correlation analysis, which is controlled by the movement of the Che-Mo plaeo uplift. Overall, oil accumulation is characterized by the superposition of two sets of source rocks for two stages in the Shawan depression. 相似文献
6.
ZHANG Gongcheng WU Aijun LI Hongyi QU Hongjun LI Youchuan XIAO Lingli ZHANG Zhenyu SHEN Jiao 《《地质学报》英文版》2021,95(1):192-207
Beibuwan B asin is an important offshore oil and gas bearing basin of China.However,the distribution of oil and gas in different sags is uneven,and the rule of hydrocarbon accumulation and main controlling factors have not been clearly understood in this basin.Based on abundant seismic,well and analytical data,the differences and main controlling of tectonic evolution,sedimentary filling and source rock quality in sags are analyzed,and combined with the study of geothermal filed,the main controlling factors of differential hydrocarbon generation in sags of the Beibuwan Basin are clarified.On the basis of the research above,the hydrocarbon enrichment of the basin is clarified through the systematic analysis of reservoir-caprock assemblage and accumulation characteristics of different structural units.The results show that there are four NE-trending sag zones in the basin,and under the influence of fault activity,the scale of sags is regularly distributed.The scale of rifts in different sag zones decreases gradually from northwest to southeast and the scale of rifts in the middle of a single sag zone is normally larger than that at two ends.Under the control of the sag-controlling faults activity,paleoproductivity and organic matter preservation conditions,the quality of source rocks in sags of the Beibuwan Basin decreases from northwest to southeast.The hydrocarbon-rich sags in the Beibuwan Basin were formed under the control of source rocks and geothermal field,and the distribution of large-medium scale fields is controlled by the favorable structural traps in the rift strata of inner gentle slope zone.The understanding of the hydrocarbon enrichment and main controlling factors in the Beibuwan Basin also provides a significant guidance for the oil and gas exploration in other rift basins. 相似文献
7.
Pang Xiong Chen Changmin Zhu Ming He Min Shen Jun Lian Shiyong Wu Xiangjie Shao Lei 《中国地质大学学报(英文版)》2009,20(1)
A significant geologic event occurred on the Oligocene/Miocene boundary at 23.8 Ma in the northern South China Sea,which is named the Baiyun (白云) movement in this article.This event strongly affected not only the South China Sea,but also East Asia.After the Balyun event,the ridge of seafloor spreading of the South China Sea Jumped southward and rotated counterclockwise,and a strong subsidence occurred in the Baiyun sag of the Pearl River Month basin.The shelf break shifted suddenly from the south to the north of the Baiyun sag,and the deposition environment in this sag changed from continental shelf with neritic deposition to continental slope with deep-water deposition.Sediment geochemistry study indicated that the Balyun event played a key role in the rapid change of sediment provenance for the Pearl River Mouth basin.Between 32 and 23.8 Ma,the source of sediments was mainly from the granites in South China,while after 23.8 Ma some sediments might have come from the eastern Himalaya,as the Pearl River drainage extended westward after the uplift of Tibet since that time.The Baiyun event led to a great change in the drainage framework of the paleoPearl River,sediment types and the depositional environments in the Pearl River Mouth basin,and relative sea level of the northern South China Sea,as well as sedimentation and hydrocarbon accumulation in the ares. 相似文献
8.
YU Yixin ZHANG Tianlong ZHANG Zhongtao ZHANG Gongcheng ZENG Jianhui YANG Haizhang ZHAO Zhao LIANG Weiwei 《《地质学报》英文版》2021,95(1):21-29
The Yunkai low uplift with low exploration degree is close to the Baiyun sag,and has hydrocarbon exploration potential in the deepwater area of the Pearl River Mouth Basin.Based on seismic and drilling data,balanced profiles and growth strata,this paper mainly discusses geological structures and formation processes of the Yunkai low uplift,and also analyzes the characteristics of fault system and their influence on hydrocarbon migration and accumulation.The EWtrending basement faults divide the Yunkai low uplift into two parts,i.e.the southern sector and the northern sector.The northern sector is a relatively wide and gentle uplift,while the southern sector is composed of two secondary half-grabens with faulting in the south and overlapping in the north.The Yunkai low uplift experienced three major formation stages,including the rapid uplifting stage during the deposition period of the Eocene Wenchang Formation,the slow uplifting stage during the deposition period of the Late Eocene-Middle Miocene Enping-Hanjiang formations,and the whole burial stage from the Middle Miocene to present.The extensional faults in the Yunkai low uplift and its adjacent areas strike mainly along the NW,NWW and near-EW directions.Also,the strikes of faults present a clockwise rotation from the deep to the shallow strata.According to effects of faults on hydrocarbon accumulation the faults in the Yunkai low uplift and its adjacent areas can be divided into trap-controlled faults and source-controlled faults.The trap-controlled faults control trap development and can effectively seal oil and gas.The source-controlled faults connect directly source rocks and reservoirs,which are highly active during the rifting stage and weakly active since the Miocene.This activity features of the source-controlled faults is beneficial to migration of the early crude oil from the Baiyun sag to the high part of the Yunkai low uplift,but is not good for migration of the late natural gas.In the Yunkai low uplift and its adjacent areas,the traps in the deep Zhuhai and Enping formations that are close to source rocks in the Baiyun sag should be the favorable exploration objectives. 相似文献
9.
REN Zhanli CUI Junping LIU Chiyang LI Tiejun CHEN Gang DOU Shuang TIAN Tao LUO Yating 《《地质学报》英文版》2015,89(2):467-484
The Qiangtang basin is located in the central Tibetan Plateau. This basin has an important structural position,and further study of its tectonic and thermal histories has great significance for understanding the evolution of the Tibetan Plateau and the hydrocarbon potential of marine carbonates in the basin. This study focuses on low temperature thermochronology and in particular conducted apatite fission track analysis. Under constraints provided by the geological background,the thermal history in different tectonic units is characterized by the degree of annealing of samples,and the timing of major(uplift-erosion related) cooling episodes is inferred. The cooling history in the Qiangtang basin can be divided into two distinct episodes. The first stage is mainly from the late Early Cretaceous to the Late Cretaceous(69.8 Ma to 108.7 Ma),while the second is mainly from the MiddleLate Eocene to the late Miocene(10.3 Ma to 44.4 Ma). The first cooling episode records the uplift of strata in the central Qiangtang basin caused by continued convergent extrusion after the BangongNujiang ocean closed. The second episode can be further divided into three periods,which are respectively 10.3 Ma,22.6–26.1 Ma and 30.8–44.4 Ma. The late Oligocene-early Miocene(22.6–26.1 Ma) is the main cooling period. The distribution and times of the earlier uplift-related cooling show that the effect of extrusion after the collision between Eurasian plate and India plate obviously influenced the Qiangtang basin at 44.4 Ma. The Qiangtang basin underwent compression and started to be uplifted from the middle-late Eocene to the early Oligocene(45.0–30.8 Ma). Subsequently,a large-scale and intensive uplift process occurred during the late Oligocene to early Miocene(26.1–22.6 Ma) and the basin continued to undergo compression and uplift up to the late Miocene(10.3 Ma). Thus,uplift-erosion in the Qiangtang basin was intensive from 44.5 Ma to about 10 Ma. The timing of cooling in the second episode shows that the uplift of the Qiangtang basin was caused by the strong compression after the collision of the Indian plate and Eurasian plate. On the whole,the new apatite fission-track data from the Qiangtang basin show that the Tibetan Plateau started to extrude and uplift during 45–30.8 Ma. The main period of uplift and formation of the Tibetan Plateau took place about 22.6–26.1 Ma,and uplift and extrusion continued until the late Miocene(10.3 Ma). 相似文献
10.
Quantitative studies on the evolution and dynamics of the deepwater area of Pearl River Mouth basin (PRMB) were carried out based on the latest geological and seismic data.The study area is generally in an extensional state during the Cenozoic.The major extension happened in the earlier syn-rift stages before 23 Ma and the extension after 23 Ma is negligible.Two rapid subsidence periods,32-23 Ma and 5.3-2.6 Ma,are identified,which are related to the abrupt heat decay during margin breakup and the collision between the Philippine Sea plate and the Eurasian plate,respectively.The strongest crustal thinning in the Baiyun (白云) sag may trigger the syn-rift volcanism along the weak faulted belt around the sag.The Cenozoic tectonic evolution of the study area could be divided into five stages:rifting (~0-40 Ma),rift-driR transition (~40-32 Ma),early post-breakup (~32-23 Ma),thermal subsidence (~23-5.3 Ma) and neotectonic movement (~5.3-0 Ma). 相似文献
11.
石炭-二叠系煤成气藏是冀中坳陷东北部亟待突破的勘探领域。文中基于大量的钻井、测井、地球化学和古地温资
料,分别模拟构建了大城凸起、文安斜坡和武清凹陷的埋藏史和考虑岩浆热液侵入作用的热演化史。研究结果表明冀中坳
陷东北部石炭-二叠系地层总体上经历了“三沉两抬”的构造演化过程,在印支运动前全区具有近似的演化历史,印支
期、燕山期区内构造演化开始分异,至新生代形成总体“东隆西坳”的构造格局。区内烃源岩热演化包括一次生烃和二次
生烃,并可细分为长期隆升型、后期强烈沉降深成变质型和岩浆热变质型三种类型。一次成烃主要发生在三叠系末期,二
次成烃分别在新近纪和古近纪岩浆侵入期。区内斜坡浅部和隆起区一次成烃,斜坡和凹陷深部为后期强烈沉降深成变质二
次成烃、斜坡和凸起岩浆热液侵入区发生岩浆热变质二次成烃。一次成烃期Ro 值在0.7%左右,不具成藏潜力,二次成烃
期烃源岩可达高熟、过熟阶段,成藏配置条件好,成藏潜力巨大。 相似文献
料,分别模拟构建了大城凸起、文安斜坡和武清凹陷的埋藏史和考虑岩浆热液侵入作用的热演化史。研究结果表明冀中坳
陷东北部石炭-二叠系地层总体上经历了“三沉两抬”的构造演化过程,在印支运动前全区具有近似的演化历史,印支
期、燕山期区内构造演化开始分异,至新生代形成总体“东隆西坳”的构造格局。区内烃源岩热演化包括一次生烃和二次
生烃,并可细分为长期隆升型、后期强烈沉降深成变质型和岩浆热变质型三种类型。一次成烃主要发生在三叠系末期,二
次成烃分别在新近纪和古近纪岩浆侵入期。区内斜坡浅部和隆起区一次成烃,斜坡和凹陷深部为后期强烈沉降深成变质二
次成烃、斜坡和凸起岩浆热液侵入区发生岩浆热变质二次成烃。一次成烃期Ro 值在0.7%左右,不具成藏潜力,二次成烃
期烃源岩可达高熟、过熟阶段,成藏配置条件好,成藏潜力巨大。 相似文献
12.
昌潍坳陷潍北凹陷热历史和油气成藏期次 总被引:8,自引:2,他引:8
根据镜质体反射率数据和磷灰石裂变径迹数据模拟计算了昌潍坳陷潍北凹陷 6口井的热演化历史,认为在孔店组沉积时期的古地温梯度较高,可达 4.4~53℃/100m,随后地温梯度逐渐降低,沙河街组四段沉积时期为 4.2~49℃/100m,馆陶组沉积时期为 4.0~47℃/km,现今为 3.8~4.2℃/km。同时,根据测量的包裹体均一温度数据和恢复样品的沉积埋藏历史、源岩的热演化历史和生烃史,认为该区有两期油气充注,第一期在孔店组沉积末期(距今 52~50.5Ma),第二期发生在沙河街组四段沉积中期至沙河街构造运动期间(距今 43.5~36Ma)。沙河街构造运动对潍北凹陷的油气成藏有重要影响,潍北凹陷的油气充注以第二期的充注为主。 相似文献
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临清坳陷东部石炭-二叠系二次生烃差异性研究 总被引:2,自引:0,他引:2
受盆地多旋回叠加和反转演化控制,临清坳陷东部石炭-二叠系含煤系地层烃源岩经历了二次生烃过程,并在空间上表现出强烈的差异性。通过对这套烃源岩生烃史模拟结果表明,石炭-二叠系烃源岩于早中三叠世进入生烃门限,随后印支运动造成全区生烃中止,中新生代烃源岩再次深埋,发生二次生烃作用。不同井区二次生烃在时间和空间上存在差异性,洼陷带发育三个“二次生烃”阶段,生烃高峰期发生在新生代,凸起带发育两个“二次生烃”阶段,生烃高峰期发生在中生代,隆起区尚未发生二次生烃。二次生烃早期生成的烃类基本遭受破坏,晚期生成的烃类具备成藏条件,是勘探的主要目标。现今洼陷带烃源岩已进入成熟-高成熟阶段,成为晚期煤成气藏的气灶。 相似文献
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为了研究鄂尔多斯盆地南部延长组油气成藏期次和成藏模式,采取镜下观察、激光拉曼、显微测温等方法对盆地南部地区延长组储层成岩作用和包裹体的特征进行了研究,并结合烃源岩生烃史、盆地热演化史,综合分析研究区延长组成藏期次。研究结果表明:鄂尔多斯盆地南部地区延长组存在两期油气包裹体:第一期油气包裹体在荧光显微镜下呈蓝绿色或深绿色的液烃包裹体,丰度较低,伴生的盐水包裹体均一温度主峰为100~110 ℃;第二期油气包裹体以气液烃包裹体为主,包裹体在单偏光下为无色或淡黄色,荧光显微镜下为亮蓝色,丰度较高,伴生的盐水包裹体均一温度主峰为130~140 ℃。通过对油气包裹体的均一温度、盐度、密度研究明确了研究区为“一期两幕”成藏,结合盆地热演化史认为鄂尔多斯盆地南部地区延长组存在两次油气充注:第一次油气充注在早白垩世中期(距今115~125 Ma),第二次油气充注主要在早白垩世晚期(距今97~105 Ma)。两次油气充注表明鄂尔多斯盆地南部地区延长组油气成藏时期为早白垩世(距今97~125 Ma)。 相似文献
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深层油气成藏机理研究的首要前提是要明确烃源岩的热演化历史,这对区域油气勘探潜力的评价有着重要的指导意义。鄂尔多斯盆地西南缘蓟县系烃源岩在中生代以来的热演化史有何特征,是否受早白垩世岩浆热作用的影响,影响程度如何等问题的不明确,制约着人们对该地区中元古界烃源岩的生烃潜力的认识及进一步勘探开发的思路。通过对安口—铜城地区出露的三叠系、侏罗系及铜城岩体进行磷灰石裂变径迹、磷灰石/锆石(U-Th)/He测试,结合镜质组反射率数据,分别恢复了该地区沉积岩在中三叠世以来和侵入岩在早白垩世以来的冷却历史,结合岩浆岩体的空间分布特征和泥页岩镜质组反射率,估算蓟县系烃源岩古地温。热年代学模拟表明,蓟县系烃源岩自中生代以来先后经历了三叠纪—侏罗纪的正常埋深增温,达到了生烃温度门限,自早白垩世约130~110 Ma开始冷却,其中个别样品表现为自始新世中期至45 Ma微弱加速冷却,中新世晚期至8 Ma以来快速冷却。研究表明,中晚侏罗世是鄂尔多斯盆地西南缘蓟县系生烃的关键时期,烃源岩处于主生油温度范围,之后的早白垩世晚期岩浆侵入事件的热作用范围有限,对蓟县系烃源岩古地温的影响仅发生在局部地区。鄂尔多斯盆地西南缘... 相似文献
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呼和湖凹陷下白垩统烃源岩生油条件好,油气资源潜力大.利用研究区7口钻井270个热解资料和125个镜质体反射率数据,分析了下白垩统烃源岩地球化学特征及热演化史.下白垩统烃源岩有机质类型主要为Ⅲ-Ⅱ2型干酪根,现今热演化程度具有中间高、四周低的特点.主力烃源岩层南屯组属于中等-好烃源岩,在约128 Ma进入生烃门限,现今处于高成熟-生气阶段.大磨拐河组属于差-中等烃源岩,在约124 Ma进入生烃门限,现今处于中等-低成熟阶段,大磨拐河组二段烃源岩至今未进入生烃高峰.热史模拟表明呼和湖凹陷在伊敏组沉积晚期达到最大古地温,地温演化具有先升高后降低的特点.从南屯组沉积至今,地温梯度先升高到50~55℃/km,后逐渐降低为现今的35.4℃/km.早白垩世以来较高的地温场对油气生成、成藏起控制作用.包裹体均一温度结合热演化史结果表明126~87 Ma(伊敏组沉积时期)应是呼和湖凹陷油气主成藏期.晚白垩世以来盆地发生抬升,温度降低,烃源岩生烃强度减弱. 相似文献
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<正>The Bohai Bay Basin is a Mesozoic subsidence and Cenozoic rift basin in the North China Craton.Since the deposition of the Permo-Carboniferous hydrocarbon source rock,the basin has undergone many tectonic events.The source rocks have undergone non-uniform uplift,twisting,deep burying,and magmatism and that led to an interrupted or stepwise during the evolution of hydrocarbon source rocks.We have investigated the Permo-Carboniferous hydrocarbon source rocks history of burying,heating,and hydrocarbon generation,not only on the basis of tectonic disturbance and deeply buried but also with new studies on apatite fission track analysis,fluid inclusion measurements,and the application of the numerical simulation of EASY%R_o.The heating temperature of the source rocks continued to rise from the Indosinian to Himalayan stage and reached a maximum at the Late Himalayan.This led to the stepwise increases during organic maturation and multiple stages of hydrocarbon generation.The study delineated the tectonic stages, the intensity of hydrocarbon generation and spatial and temporal distribution of hydrocarbon generations.The hydrocarbon generation occurred during the Indosinian,Yanshanian,and particularly Late Himalayan.The hydrocarbon generation during the late Himalayan stage is the most important one for the Permo-Carboniferous source rocks of the Bohai Bay Basin in China. 相似文献