吉林大学学报(地球科学版) ›› 2020, Vol. 50 ›› Issue (3): 732-746.doi: 10.13278/j.cnki.jjuese.20190013
• 地质与资源 • 上一篇
李勇1,2, 陈世加1,2,3, 尹相东1,2, 何清波2, 苏恺明2, 肖正录2, 邱雯2, 何鑫2
Li Yong1,2, Chen Shijia1,2,3, Yin Xiangdong1,2, He Qingbo2, Su Kaiming2, Xiao Zhenglu2, Qiu Wen2, He Xin2
摘要: 固体沥青包含了油气形成与演化等重要信息,其研究对油气勘探与开发具有重要的指导作用。综合国内外众多学者的研究,阐述了固体沥青的定义、成因与分类、反射率、对储层物性的影响及测井识别。固体沥青成因类型多样,归纳起来主要包括热成因和冷变质成因两大类。固体沥青反射率可以作为成熟度评价的有效参数,但需结合实际地质情况合理选择转换关系式。固体沥青充填在储集层孔隙空间中,堵塞孔隙喉道:一方面造成储集层的严重损害,导致油藏分布不均;另一方面作为封堵带,有利于油气的保存,形成隐蔽油气藏。固体沥青在核磁共振上具有独特的响应特征,利用核磁共振T1/T2值、中子-密度交会、密度孔隙度与气测孔隙度差值以及纵波时差-电阻率交会可以有效识别固体沥青。对于固体沥青后续研究,固体沥青结构、性质与固体沥青反射率的关系,以及如何使用测井参数定量标定固体沥青体积分数,是未来固体沥青在储层评价和油气开发研究的热点和难点。
中图分类号:
[1] Hwang R J,Teerman S C,Carlson R M. Geochemical Comparison of Reservoir Solid Bitumen with Diverse Origins[J]. Organic Geochemistry,1998,29(1/2/3):505-517. [2] Stasuik L D. The Origin of Pyrobitumens in Upper Devonian Leduc Formation Gas Reservoirs, Alberta, Canada:An Optical and EDS Study of Oil to Gas Transformation[J].Marine & Petroleum Geology,1997,14(7/8):915-929. [3] 李文强,郭巍,孙守亮,等.塔里木盆地巴楚-麦盖提地区古生界油气成藏期次[J].吉林大学学报(地球科学版),2018,48(3):640-651. Li Wenqiang,Guo Wei,Sun Shouliang,et al. Research on Hydrocarbon Accumulation Periods of Palaeozoic Reservoirs in Bachu-Maigaiti Area of Tarim Basin[J]. Journal of Jilin University(Earth Science Edition),2018,48(3):640-651. [4] 林敉若,操应长,葸克来,等.阜康凹陷东部斜坡带二叠系储层特征及控制因素[J].吉林大学学报(地球科学版),2018,48(4):991-1007. Lin Miruo,Cao Yingchang,Xi Kelai,et al. Characteristics and Controlling Factors of Permian Reservoirs in East Slope of Fukang Sag[J]. Journal of Jilin University(Earth Science Edition),2018,48(4):991-1007. [5] Li Y,Chen S J,Wang Y X,et al. Relationships Between Hydrocarbon Evolution and the Geochemistry of Solid Bitumen in the Guanwushan Formation,NW Sichuan Basin[J]. Marine and Petroleum Geology,2020,111:116-134. [6] 刘洛夫,赵建章,张水昌,等.塔里木盆地志留系沥青砂岩的成因类型及特征[J].石油学报,2000,21(6):12-17. Liu Luofu,Zhao Jianzhang,Zhang Shuichang,et al. Genetic Types and Characteristic of the Silurian Asphaltic Sandstones in Tarim Basin[J]. Acta Petrolei Sinica,2000,21(6):12-17. [7] 陈强路,范明,尤东华.塔里木盆地志留系沥青砂岩储集性非常规评价[J].石油学报,2006,27(1):30-33. Chen Qianglu,Fan Ming,You Donghua. Non-Traditional Method for Evaluating Physical Property of Silurian Bitumen Sandstone Reservoir in Tarim Basin[J]. Acta Petrolei Sinica,2006,27(1):30-33. [8] 路俊刚,陈世加,王绪龙,等.准东三台-被三台地区储层沥青和稠油特征与成因分析[J].中国石油大学学报(自然科学版),2011,35(5):27-31. Lu Jungang,Chen Shijia,Wang Xulong,et al. Characteristics and Origin Analysis of Viscous Oil and Reservoir Bitumen in Santai-Beisantai Area[J]. Journal of China University of Petroleum,2011,35(5):27-31. [9] 路俊刚,陈世加,王绪龙,等.严重生物降解稠油成熟度判识:以准噶尔盆地三台-北三台地区为例[J].石油实验地质,2010,32(4):373-376. Lu Jungang,Chen Shijia,Wang Xulong,et al. Maturity Study of the Strong Biodegradation Viscous Oil:Taking the Santai-Beisantai Area of Junggar Basin as An Example[J]. Petroleum Geology & Experiment,2010,32(4):373-376. [10] Jacob H. Classification,Structure,Genesis and Practical Importance of Natural Solid Oil Bitumen ("Migrabitumen")[J]. International Journal of Coal Geology,1989,11(1):65-79. [11] 刘伟新,把立强,张美珍,等.石油地质分析测试技术新进展[J].石油实验地质,2003,25(6):777-782. Liu Weixin,Ba Liqiang,Zhang Meizhen,et al. New Technological Advances in Petroleum Exploration[J]. Petroleum Geology & Experiment,2003,25(6):777-782. [12] 胡守志,付晓文,王廷栋,等.储层中的沥青沉淀带及其对油气勘探的意义[J].天然气地球科学,2007,18(1):99-103. Hu Shouzhi,Fu Xiaowen,Wang Tingdong,et al. Bitumen-Sealed Belt in Reservoirs and Its Implication to Petroleum Exploration[J]. Natural Gas Geoscience,2007,18(1):99-103. [13] 黄文明,徐邱康,刘树根,等.中国海相层系油气成藏过程与储层沥青耦合关系:以四川盆地为例[J].地质科技情报,2015,34(6):159-168. Huang Wenming,Xu Qiukang,Liu Shugen,et al. Coupling Relationship Between Oil & Gas Accumulation Process and Reservoir Bitumen of Marine System:Taking Sichuan Basin as an Example[J]. Geological Science and Technology Information,2015,34(6):159-168. [14] 付小东,秦建中,腾格尔,等.固体沥青:反演油气成藏及改造过程的重要标志[J].天然气地球科学,2009,20(2):167-173. Fu Xiaodong,Qin Jianzhong,Ten Geer,et al. Solid Bitumen:An Important Sign of Inverting the Process of Hydrocarbon Accumulation and Reconstruction[J]. Natural Gas Geoscience,2009,20(2):167-173. [15] 秦胜飞,潘文庆,韩剑发,等.储层沥青与有机包裹体生物标志物分析方法[J].石油实验地质,2007,29(3):315-328. Qin Shengfei,Pan Wenqing,Han Jianfa,et al. A Method for Biomarker Study from Reservoir Bitumen and Inclusions[J]. Petroleum Geology & Experiment,2007,29(3):315-328. [16] 田兴旺,胡国艺,李伟,等. 四川盆地乐山-龙女寺古隆起地区震旦系储层沥青地球化学特征及意义[J].天然气地球科学,2013,24(5):982-990. Tian Xingwang,Hu Guoyi,Li Wei,et al. Geochemical Characteristics and Significance of Sinian Reservoir Bitumen in Leshan-Longnvsi Paleo-Uplift Area,Sichuan Basin[J]. Natural Gas Geoscience,2013,24(5):982-990. [17] 谢增业,田世澄,魏国齐,等.川东北飞仙关组储层沥青与古油藏研究[J].天然气地球科学,2005,16(3):15-16. Xie Zengye,Tian Shicheng,Wei Guoqi,et al. The Study on Bitumen and Foregone Pool of Feixianguan Oolitic in Northeast Sichuan Basin[J]. Natural Gas Geoscience,2005,16(3):15-16. [18] 金晓东,潘长春,于双,等.普光气田及邻区碳酸盐储层沥青的分子地球化学研究[J].地球化学,2012,41(4):293-302. Yu Xiaodong,Pan Changchun,Yu Shuang,et al. Molecular Geochemistry of Solid Bitumen-Bearing Carbonate Reservoir Rocks from the Puguang Gas Field and Nearby Areas[J]. Geochimica,2012,41(4):293-302. [19] 凡元芳.储层沥青的研究进展及存在问题[J].石油地质与工程,2009,23(6):35-38. Fan Yuanfang. Advance and Main Problems in Reservoir Bitumen Research[J]. Petroleum Geology and Engineering,2009,23(6):35-38. [20] 纪友亮.固态沥青对储层储集性能的影响[J].石油勘探与开发,1995,22(4):87-91. Ji Youliang. The Effect of Solid Reservoir Bitumen on Reservoir Quality[J]. Petroleum Exploration and Development,1995,22(4):87-91. [21] 陈世加,范小军,路俊刚,等.沥青对储集层物性及油气富集的影响[J].石油勘探与开发,2010,37(1):30-76. Chen Shijia,Fan Xiaojun,Lu Jungang,et al. Impact of Bitumen on Reservoir Properties and Hydrocarbon Accumulation[J]. Petroleum Exploration and Development,2010,37(1):30-76. [22] Archie G E. The Electrical Resistivity Log as an Aid in Determining Some Reservoir Characteristics[J]. Transactions of the AIME,1942,146(1):54-62. [23] Hirasaki G J,Lo S W,Zhang Y. NMR Properties of Petroleum Reservoir Fluids[J]. Magnetic Resonance Imaging,2003,21(3):269-277. [24] Akkurt R,Seifert D,Harbi A,et al. Real-Time Detection of Tar in Carbonates Using LWD Triple Combo,NMR and Formation Tester in Highly-Deviated Wells[J]. Petrophysics,2009,50(2):140-152. [25] Rogers M A. Significance of Reservoir Bitumen to Thermal Maturation Studies Western Canada Basin[J]. AAPG Bulletin,1974,58(9):1806-1824. [26] van Gijzel P. Applications of the Geomicrophotometry of Kerogen,Solid Hydrocarbons and Crude Oils to Petroleum Exploration[M]//Brooks J. Organic Maturation Studies and Fossil Fuel Exploration. London:Academic Press,1981:351-377. [27] Jacob H. Disperse Solid Bitumens as an Indicator for Migration and Maturity in Prospecting for Oil and Gas[J]. Erdol and Kohle,1985,38:364-366. [28] Dai Q,Chung K H. Bitumen-Sand Interaction in Oil Sand Processing[J]. Fuel,1995,74(12):1858-1864. [29] Lomando A J.The Influence of Solid Reservoir Bitumen on Reservoir Quality[J]. AAPG,1992,76(8):1137-1152. [30] Wilhelms A, Larter S R. Overview of the Geochemistry of Some Tar Mats from the North Sea and USA:Applications for Tar-Mat Origin[J]. Geological Society Special Publication,1995,86(1):87-101. [31] 梁狄刚,黄第藩,马新华,等.有机地球化学研究新进展[M].北京:石油工业出版社,2002:423-427. Liang Digang,Huang Difan,Ma Xinhua,et al. New Progress in Organic Geochemistry[M]. Beijing:Petroleum Industry Press,2002:423-427. [32] Evans C R,Rogers M A,Bailey N J L. Evolution and Alteration of Petroleum in Western Canada[J]. Chemical Geology,1971,8(3):147-170. [33] Dahl B,Speers G C. Geochemical Characterization of a Tar Mat in the Oseberg Field Norwegian Seetor, North Sea[J]. Organic Geochemistry, 1986, 10(2):547-558. [34] Lafargue E,Le Thiez P. Effect of Waterwashing on Light Ends Compositional Heterogeneity[J]. Organic Geochemistry,1996,24(12):1141-1150. [35] Head I M,Jones D M,Larter S R. Biological Activity in the Deep Subsurface and the Origin of Heavy Oil[J]. Nature,2003,426:344-352. [36] Kim D,Philp R P,Sorenson R P. Geochemical Characterization of Solid Bitumen in the Chesterian (Mississippian) Sandstone Reservoir of the Hitch Field,Southwest Kansas[J]. AAPG Bulletin,2010,94(7):1031-1057. [37] Kelemen S R,Walters C C,Kwiatek P J,et al. Characterization of Solid Bitumens Originating from Thermal Chemical Alteration and Thermochemical Sulfate Reduction[J]. Geochimica et Cosmochimica Acta,2010,74(18):5305-5332. [38] Walters C C,Qian K,Wu C,et al. Proto-Solid Bitumen in Petroleum Altered by Thermochemical Sulfate Reduction[J]. Organic Geochemistry,2011,42(9):999-1006. [39] Hu A,Li M,Wong J,et al. Chemical and Petrographic Evidence for Thermal Cracking and Thermochemical Sulfate Reduction of Paleo-Oil Accumulations in the NE Sichuan Basin,China[J]. Organic Geochemistry,2010,41(9):924-929. [40] 陈哲龙,柳广弟,曹正林,等.储层沥青成因极其石油地质意义:以准噶尔盆地玛湖凹陷百口泉组为例[J].中国矿业大学学报,2018,42(2):391-399. Chen Zhelong,Liu Guangdi,Cao Zhenglin,et al. Origin of Solid Bitumen and Its Significance to Petroleum Geology:A Case Study of Baikouquan Formation in Mahu Sag of Junggar Basin[J]. Journal of China University of Mining & Technology,2018,42(2):391-399. [41] Gao Z N,Chen Y Y,Niu F. Compressively Matured Solid Bitumen and Its Geochemical Significance[J]. Geochemical Journal,2001,35(3):155-168. [42] Hill R J,Tang Y C,Kaplan I R. Insights Into Oil Cracking Based on Laboratory Experiments[J]. Organic Geochemistry,2003,34:1651-1672. [43] Dahl J E,Moldowan J M,Peters K E,et al. Diamondoid Hydrocarbons as Indicators of Natural Oil Cracking[J]. Nature, 1999,399:54-57. [44] Horsfield B,Schenk H J,Mills N,et al. An Investigation of the In-Reservoir Conversion of Oil to Gas:Compositional and Kinetic Findings from Closed-System Programmed-Temperature Pyrolysis[J]. Organic Geochemistry,1992,19:191-204. [45] Kelemen S R,Walters C C,Kwiatek P J,et al. Distinguishing Solid Bitumens Formed by Thermochemical Sulfate Reduction and Thermal Chemical Alteration[J]. Organic Geochemistry,2008,39:1137-1143. [46] Walters C C,Qian K,Wu C,et al. Proto-Solid Bitumen in Petroleum Altered by Thermochemical Sulfate Reduction[J]. Organic Geochemistry,2011,42:999-1006. [47] King H E,Walters C C,Horn W C,et al. Sulfur Isotope Analysis of Bitumen and Pyrite Associated with Thermal Sulfate Reduction in Reservoir Carbonates at the Big Piney-La Barge Production Complex[J]. Geochemica et Cosmochomica Acta,2014,134:210-230. [48] Cai C,Li K,Zhu Y,et al. TSR Origin of Sulfur in Permian and Triassic Reservoir Bitumen,East Sichuan Basin,China[J]. Organic Geochemistry,2010,41(9):871-878. [49] Volkman J K,Alexander R,Kagi R I,et al. Biodegradation of Aromatic Hydrocarbons in Crude Oils from the Barrow Sub-Basin of Western Australia[J]. Organic Geochemistry,1984,6:619-632. [50] Larter S,Wilhelms A,Head I,et al. The Controls on the Composition of Biodegraded Oils in the Deep Subsurface:Part 1:Biodegradation Rates in Petroleum Reservoirs[J]. Organic Geochemistry,2003,34(4):601-613. [51] 张敏,张俊.水洗作用对油藏中烃类组成的影响[J].地球化学,2000,29(3):287-292. Zhang Min,Zhang Jun. Effect of Water Washing on Hydrocarbon Compositions of Petroleum Sandstone Reservoir Rocks in Tarim Basin, NW China[J]. Geochimica,2000,29(3):287-292. [52] Shalaby M R,Hakimi M H,Wan H A. Geochemical Characterization of Solid Bitumen (Migrabitumen) in the Jurassic Sandstone Reservoir of the Tut Field, Shushan Basin, Northern Western Desert of Egypt[J]. International Journal of Coal Geology,2012,100(3):26-39. [53] 陈世加,刘超威,杨跃明,等. 川中八角场构造大安寨段凝析气藏形成机制再认识[J]. 天然气工业,2013,33(9):29-35. Chen Shijia,Liu Chaowei,Yang Yueming,et al. Restudy of the Formation Mechanism of the Da'anzhai Condensate Gas Reservoir in the Bajiaochang Structure, Middle Sichuan Basin[J]. Natural Gas Industry,2013,33(9):29-35. [54] Hunt J M,Stewart F,Dickey P A. Origin of Hydrocarbons of Uinta Basin,Utah[J]. AAPG Bulletin,1954,38:1671-1698. [55] Curiale J A. Origin of Solid Bitumens,with Emphasis on Biological Marker Results[J]. Organic Geochemistry,1986,10:559-580. [56] 张子枢.焦沥青及其反射率的测定[J].新疆石油地质,1988,9(2):24-29. Zhang Zishu. Pyrobitumen and Measurement of Its Reflectivity[J]. Xinjiang Petroleum Geology,1988,9(2):24-29. [57] 傅家谟,贾蓉芬,刘德汉,等.碳酸岩有机地球化学:在石油、天然气、煤和层控矿床成因及评价中的应用[M].北京:科学出版社,1989:77-92. Fu Jiamo,Jia Rongfen,Liu Dehan,et al. Organic Geochemistry of Carbonate Sediments Applications in Origin and Evaluation of Oil, Gas, Coal and Strata-bound Resources[M]. Beijing:Science Press,1989:77-92. [58] Bertrand R. Standardization of Solid Bitumen Reflectance to Vitrinite in Some Paleozoic Sequences of Canada[J]. Energy Sources,1993,15:269-287. [59] Riediger C L. Solid Bitumen Reflectance and Rock-Eval Tmax as Maturation Indices:An Example from the "Nordegg Member",Western Canada Sedimentary Basin[J]. International Journal of Coal Geology,1993,22:295-315. [60] Landis C R,Castaño J R. Maturation and Bulk Chemical Properties of a Suite of Solid Hydrocarbons[J]. Organic Geochemistry,1995,22(1):137-149. [61] Bertrand R,Malo M. Source Rock Analysis, Thermal Maturation and Hydrocarbon Generation in Siluro-Devonian Rocks of the Gaspe' Belt Basin, Canada[J]. Bulletin of Canadian Petroleum Geology,2001,49(2):238-261. [62] Schoenherr J, Littke R,Urai J L,et al. Polyphase Thermal Evolution in the Infra-Cambrian Ara Group (South Oman Salt Basin) as Deduced by Maturity of Solid Reservoir Bitumen[J]. Organic Geochemistry,2007,38(8):1293-1318. [63] Valentine B J,Hackley P C,Enomoto C B,et al. Organic Petrology of the Aptian-Age Section in the Downdip Mississippi Interior Salt Basin, Mississippi,USA:Observations and Preliminary Implications for Thermal Maturation History[J]. International Journal of Coal Geology,2014,136:38-51. [64] Wei L,Mastalerz M,Schimmelmann A. Comparative Optical Properties of Vitrinite and Other Macerals from Upper Devonian-Lower Mississippian New Albany Shale:Implications for Thermal Maturity[J]. International Journal of Coal Geology,2016,168:222-236. [65] Liu B,Schieber J,Mastalerz M. Combined SEM and Reflected Light Petrography of Organic Matter in the New Albany Shale:A Perspective on Organic Porosity Development with Thermal Maturation[J]. International Journal of Coal Geology,2017,184:57-72. [66] Mastalerz M,Drobniak A,Stankiewicz A B. Origin, Properties, and Implications of Solid Bitumen in Source-Rock Reservoirs:A Review[J]. International Journal of Coal Geology,2018,195:14-36. [67] Gonçalves P A,Filho J G,da Silva F S,et al. Solid Bitumen Occurrences in the Arruda Sub-Basin (Lusitanian Basin, Portugal):Petrographic Features[J]. International Journal of Coal Geology,2015,139:217-227. [68] McFadzean T B. Rock-Fluid Relationship Studies on the Windfall D-3A Reservoir and Their Application in Evaluating Gas Cycling Effectiveness[J]. Journal of Canadian Petroleum Technology,1997,16(1):55-63. [69] Mohnhoff D,Littke R,Krooss B M,et al. Flow-Through Extraction of Oil and Gas Shales Under Controlled Stress Using Organic Solvents:Implications for Organic Matter-Related Porosity and Permeability Changes with Thermal Maturity[J]. International Journal of Coal Geology,2016,157:84-99. [70] Wood J M,Sanei H,Curtis M E,et al. Solid Bitumen as a Determinant of Reservoir Quality in an Unconventional Tight Gas Siltstone Play[J]. International Journal of Coal Geology,2015,150/151:287-295. [71] Moore L V. Significance, Classification of Asphaltic Material in Petroleum Exploration[J]. Oil & Gas Journal,1984,82(41):109-112. [72] 蒋有录,刘华. 断裂沥青带及其油气地质意义[J].石油学报,2010,31(1):36-41. Jiang Youlu,Liu Hua. Fault Asphalt Zone and Its Significance in Petroleum Geology[J]. Acta Petrolei Sinica,2010,31(1):36-41. [73] 陈世加,张焕旭,路俊刚,等. 四川盆地中部侏罗系大安寨段致密油富集高产控制因素[J].石油勘探与开发,2015,42(2):186-193. Chen Shijia,Zhang Huanxu,Lu Jungang,et al. Controlling Factors of Jurassic Da'anzhai Member Tight Oil Accumulation and High Production in Central Sichuan Basin, SW China[J]. Petroleum Exploration and Development,2015,42(2):186-193. [74] 陈世加,姚泾利,路俊刚,等. 储层沥青成因及其对油气运聚的影响:以鄂尔多斯盆地华庆地区长8油层组1砂组为例[J].石油与天然气地质,2012,33(1):37-44. Chen Shijia,Yao Jingli,Lu Jungang,et al. Reservoir Bitumen Genesis and Its Impacts on Hydrocarbon Migration and Accumulation:A Case Study from Chang 81of Yangchang Fomation in Huaqing Area,the Ordos Basin[J]. Oil & Gas Geology,2012,33(1):37-44. [75] Nascimento J D S,Gomes R M R. Tar Mats Characterization from NMR and Conventional Logs, Case Studies in Deepwater Reservoirs, Offshore Brazil[C]//SPWLA 45th Annual Logging Symposium. Noordwijk:Society of Petrophysicists and Well-Log Analysts, 2004:8. [76] Akkurt R,Seifert D,Al-Harbi A,et al. Real-Time Detection of Tar in Carbonates Using LWD Triple Combo, NMR and Formation Tester in Highly-Deviated Wells[J]. Petrophysics,2009,50(2):140-152. [77] Saidian M,Rasmussen T,Nasser M,et al. Qualitative and Quantitative Reservoir Bitumen Characterization:A Core to Log Correlation Methodology[J]. Interpretation,2014,3(1):143-158. [78] 段金宝,蔡忠贤. 用测井方法确定砂岩储层中固体沥青含量方法的探讨[J].新疆石油天然气,2006,2(2):29-32. Duan Jinbao,Cai Zhongxian. Probe into the Method to Calculate the Content of Solid Bitumen in Sandstone Reservoir by Logging[J]. Xinjiang Oil & Gas,2006,2(2):29-32. [79] 陈明江,任兴国.含沥青储层的测井识别及评价[J]. 测井技术,2012,36(3):272-276. Chen Mingjiang,Ren Xingguo. Log Identification and Evaluation for Bitumen-Bearing Reservoir[J]. Well Logging Technology,2012,36(3):272-276. [80] Zou X,Chen S,Wang L,et al. Bitumen Characterization in Situ Using NMR[J]. Petroleum Science and Technology,2016,34(5):437-441. [81] 冀昆,郭少斌,李新,等. 溶孔发育的含沥青质碳酸盐岩核磁共振特征分析:以四川盆地高磨地区龙王庙组储层为例[J].天然气地球科学,2017,28(8):1257-1263. Ji Kun,Guo Shaobin,Li Xin,et al. The Nuclear Magnetic Resonance (NMR) Characteristics of the Carbonate Rock Reservoir Which Has Dissolved Pores and Asphalt[J]. Natural Gas Geoscience,2017,28(8):1257-1263. [82] 赖强,谢冰,吴煜宇,等.沥青质碳酸盐岩储集层岩石物理特征及测井评价:以四川盆地安岳气田寒武系龙王庙组为例[J].石油勘探与开发,2017,44(6):889-895. Lai Qiang,Xie Bing,Wu Yuyu,et al. Petrophysical Characteristics and Logging Evaluation of Asphaltene Carbonate Reservoirs:A Case Study of the Cambrian Longwangmiao Formation in Anyue Gas Field, Sichuan Basin[J]. Petroleum Exploration & Development,2017,44(6):889-895. |
[1] | 迟唤昭, 董福湘, 薛晓刚, 刘财, 司考. 松辽盆地南部地区营城组典型火山机构地质特征[J]. 吉林大学学报(地球科学版), 2019, 49(6): 1649-1657. |
[2] | 陈思芮, 曲希玉, 王冠民, 王清斌, 曹英权. 渤中凹陷CFD18-2油田高岭石胶结作用及其对储层物性的影响[J]. 吉林大学学报(地球科学版), 2019, 49(5): 1235-1246. |
[3] | 辛欣, 陈圣波, 覃文汉, 李东辉, 陆天启, 田粉粉. Apollo16登月区Hapke模型参数反演及模型敏感性分析[J]. 吉林大学学报(地球科学版), 2018, 48(3): 934-940. |
[4] | 邱隆伟, 师政, 付大巍, 潘泽浩, 杨生超, 曲长胜. 临南洼陷沙三段孔隙度控制因素分析与定量模型[J]. 吉林大学学报(地球科学版), 2016, 46(5): 1321-1331. |
[5] | 韦丹宁, 付广. 反向断裂下盘较顺向断裂上盘更易富集油气机理的定量解释[J]. 吉林大学学报(地球科学版), 2016, 46(3): 702-710. |
[6] | 陈彬滔, 潘树新, 梁苏娟, 张庆石, 刘彩燕, 王革. 陆相湖盆深水块体搬运体优质储层的主控因素以松辽盆地英台地区青山口组为例[J]. 吉林大学学报(地球科学版), 2015, 45(4): 1002-1010. |
[7] | 胡大千, 王岩泉, 沙茜, 王春光, 陈旭, 马瑞. 大兴安岭北部上古生界极低级变质温度——来自碳质物拉曼光谱的证据[J]. 吉林大学学报(地球科学版), 2015, 45(1): 188-197. |
[8] | 苏俊磊, 王艳, 孙建孟. 应用可变T2截止值确定束缚水饱和度[J]. J4, 2010, 40(6): 1491-1495. |
[9] | 孟治国, 陈圣波, 崔腾飞, 连懿. 基于嫦娥一号卫星激光高度计数据的月表有效反射率[J]. J4, 2010, 40(3): 721-725. |
[10] | 曹瑞成,曲希玉,文 全,鲍春艳,刘剑营,刘 娜,刘 立. 海拉尔盆地贝尔凹陷储层物性特征及控制因素[J]. J4, 2009, 39(1): 23-0030. |
[11] | 冯娟萍,李文厚,欧阳征健,余 芳,曹红霞,赵 阳. 陕北青化砭油田长2砂岩储层物性的控制因素[J]. J4, 2008, 38(3): 417-0424. |
[12] | 王涌泉,熊永强,王彦美. 川东北固体沥青的有机地球化学[J]. J4, 2008, 38(1): 76-0080. |
[13] | 高有峰,刘万洙,纪学雁,白雪峰,王璞珺,黄玉龙,郑常青,闵飞琼. 松辽盆地营城组火山岩成岩作用类型、特征及其对储层物性的影响[J]. J4, 2007, 37(6): 1251-1258. |
[14] | 吴颜雄,王璞珺,曲立才,闵飞琼,李喆,任利军. 营城组一段及下段岩性岩相和储层物性的精细刻画--基于标准剖面营一D1井全取心钻孔资料[J]. J4, 2007, 37(6): 1192-1202. |
[15] | 付 广,王国民,王有功. 贝尔凹陷布达特群垂直裂缝垂向封闭性演化特征[J]. J4, 2007, 37(5): 913-0918. |
|