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The influence of Permian igneous rock on the seismic imaging of underlying strata in Hanilcatam area,Tarim Basin

Sun Dong,Shi Xiao-qian,Wang Zhen-qing,Chen Li-xin,Wang Jing,Sun Jia-qing,Dai Dong-dong,Fang Qi-fei   

  1. 1.PetroChina Research Institute of Petroleum Exploration and Development-Northwest,Lanzhou 730020,China; 2.Exploration and Development Research Institute,Tarim Oilfield Company,PetroChina,Korla 841000,China
  • Received:2018-05-15 Revised:2018-10-23 Online:2018-12-10

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Abstract: In order to get an accurate view of the influence of thick igneous rock on the seismic imaging of the underlying strata,based on the actual drilling and logging data and the 3D seismic data,the Cambrian-Cretaceous simplified geologic model,and the finite difference method are used to solve the elastic wave equation.The forward equation simulation of the wave equation is carried out,the true restoration seismic imaging process is carried out,and the influence of the Permian igneous rock body on the seismic imaging of the underlying strata is discussed.Paleozoic oil and gas exploration and development play a certain reference.The results show that the high-speed and high-density Permian dacite have shielding effect on the seismic imaging of the underlying strata,and the amplitude of the reflected wave of the underlying strata is obviously weakened relative to the periphery of the covering area.Due to the lateral mutation of the lithology,the seismic imaging of the layers has obvious deformation and tectonic anomalies,rather than the seismic response of the fault zones or volcanic channels.The wavefield of fracture-cavern body in the disorder reflection region and underlying region of volcanics is very complex and the imaging velocity is difficult to pick accurately,which leads to distorted migration results and not convergent bead-like reflection.

Key words: Permian system, Igneous rock, Seismic imaging, Forward modeling, Carbonate rocks

CLC Number: 

  • TE132.1
[1]Zhu Guangyou,Liu Xingwang,Zhu Yongfeng,et al.The characteristics and the accumulation mechanism of complex reservoirs in the Hanilcatam area,Tarim Basin[J].Bulletin of Mineralogy,Petrology and Geochemistry,2013,32(2):231-242.
朱光有,刘星旺,朱永峰,等.塔里木盆地哈拉哈塘地区复杂油气藏特征及其成藏机制[J].矿物岩石地球化学通报,2013,32(2):231-242.
[2]Zhu Guangyou,Cui Jie,Yang Haijun,et al.The distribution and origin of Cambrian crude oil in north Tarim Basin[J].Acta Petrologica Sinica,2011,27(8):2435-2446.
朱光有,崔洁,杨海军,等.塔里木盆地塔北地区具有寒武系特征原油的分布及其成因[J].岩石学报,2011,27(8):2435-2446.
[3]Chen Hanlin,Yang Shufeng,Wang Qinghua,et al.Sedimentary response to the Early-Mid Permian basaltic magmatism in the Tarim plate[J].Geology in China,2006,33(3):545-552.
陈汉林,杨树锋,王清华,等.塔里木板块早—中二叠世玄武质岩浆作用的沉积响应[J].中国地质,2006,33(3):545-552.
[4]Chen Hanlin,Yang Shufeng,Li Zilong,et al.Spatial and temporal characteristics of Permian large igneous province in Tarim Basin[J].Xinjiang Petroleum Geology,2009,30(2):179-182.
陈汉林,杨树锋,厉子龙,等.塔里木盆地二叠纪大火成岩省发育的时空特点[J].新疆石油地质,2009,30(2):179-182.
[5]Liu Yalei,Huang Zhibin,Wu Genyao,et al.Distribution and structural setting of magmatic rocks of Middle-Late Permian in western Tabei Uplift,Tarim Basin[J].Xinjiang Petroleum Geology,2012,33(6):672-675.
刘亚雷,黄智斌,吴根耀,等.塔北隆起西部中晚二叠世岩浆岩的分布和构造背景[J].新疆石油地质,2012,33(6):672-675.
[6]Yan Lei,Li Ming,Pan Wenqing,et al.Distribution characteristics of Permian igneous rock in Tarim Basin:Based on the high-precision aeromagnetic data[J].Progress in Geophysics,2014,29(4):1843-1848.
闫磊,李明,潘文庆,等.塔里木盆地二叠纪火成岩分布特征——基于高精度航磁资料[J].地球物理学进展,2014,29(4):1843-1848.
[7]Cheng Haiyan,Li Jianghai,Zhao Xing,et al.Seismic interpretation of occurrence of Permian magmatite and its emplacement in Tabei Uplift,Tarim Basin[J].Acta Petrologica Sinica,2010,26(1):283-290.
程海燕,李江海,赵星,等.塔北隆起二叠纪岩浆岩产状的地震解释及其侵位模式[J].岩石学报,2010,26(1):283-290.
[8]Li Jun,Zhang Junhua,Han Shuang,et al.A review:Exploration status,basic characteristics and prediction approaches of igneous rock reservoir[J].Oil Geophysical Prospecting,2015,50(2):382-392.
李军,张军华,韩双,等.火成岩储层勘探现状、基本特征及预测技术综述[J].石油地球物理勘探,2015,50(2):382-392.
[9]Liu Jingyan,Liang Yunji,Liang Yanan,et al.Method for seismic data processing in igneous rock grown area of Tarim Basin[J].Journal of Oil and Gas Technology,2005,27(4):610-612.
刘景彦,梁运基,梁亚南,等.塔里木盆地火成岩发育区地震资料处理方法研究[J].石油天然气学报,2005,27(4):610-612.
[10]Pei Zhenglin,Mou Yongguang.Study on the law of seismic wave propagation in igneous rock area[J].Geophysical Prospecting for Petroleum,2004,43(5):433-437.
裴正林,牟永光.火成岩区地震波传播规律研究[J].石油物探,2004,43(5):433-437.
[11]Han Zhanyi,Shang Xinmin,Sun Chengyu,et al.Study on seismic reflection wave field characteristics of formations below igneous rock[J].Geophysical Prospecting for Petroleum,2009,48(3):226-231.
韩站一,尚新民,孙成禹,等.火成岩下伏地层地震反射波场特征研究[J].石油物探,2009,48(3):226-231.
[12]Wang Shuling.Improving the igneous rocks imaging of the lower formations with forward simulation technologies:A case study on lower igneous rocks in Yangxin Sag[J].Journal of Mineralogy and Petrology,2014,34(3):98-103.
王淑玲.利用正演模拟技术改善火成岩下目标层成像——以阳信洼陷火成岩下成像研究为例[J].矿物岩石,2014,34(3):98-103.
[13]Wu Qingling,Li Wei,Chen Kewei,et al.Reflection free wave equation modeling and its application[J].Oil Geophysical Prospecting,2000,35(2):147-153.
吴清岭,李伟,陈可为,等.无反射波动方程正演模型及其应用[J].石油地球物理勘探,2000,35(2):147-153.
[14]Wang Yongming,Wang Yanchun,Feng Xukui,et al.Influences of acquisition geometry on complex structure imaging with forward modeling[J].Oil Geophysical Prospecting,2015,50(4):580-587.
王永明,王彦春,冯许魁,等.应用模型正演方法分析观测系统对复杂构造区成像的影响[J].石油地球物理勘探,2015,50(4):580-587.
[15]Sun Dong,Wang Hongbin,Yong Xueshan,et al.Seismic response of 40m caves with different distances from limestone top boundary[J].Lithologic Reservoirs,2011,23(1):94-97.
孙东,王宏斌,雍学善,等.直径40m溶洞距灰岩顶界面不同距离时的地震响应[J].岩性油气藏,2011,23(1):94-97.
[16]Li Fanyi,Wei Jianxin,Di Bangrang,et al.Seismic physical model of carbonate cavern reservoirs[J].Oil Geophysical Prospecting,2016,51(2):272-280.
李凡异,魏建新,狄帮让,等.碳酸盐岩孔洞储层地震物理模型研究[J].石油地球物理勘探,2016,51(2):272-280.
[17]Luo Jinglan,Zhai Xiaoxian,Pu Renhai,et al.Horizon,petrology and lithofacies of the volcanic rocks in the oilfield,northern Tarim Basin[J].Chinese Journal of Geology:Scientia Geologica Sinica,2006,41(3):378-391.
罗静兰,翟晓先,蒲仁海,等.塔河油田火山岩的层位归属、火山岩岩石学与岩相学特征[J].地质科学,2006,41(3):378-391.
[18]Sun Dong,Pan Jianguo,Yong Xueshan,et al.Formation mechanism of vertical “long string beads” in carbonate reservoir[J].Oil Geophysical Prospecting,2010,45(supplement1):101-104.
孙东,潘建国,雍学善,等.碳酸盐岩储层垂向长串珠形成机制[J].石油地球物理勘探,2010,45(增刊1):101-104.
[19]Li Suhua,Wang Yunzhuan,Lu Qijun,et al.Wave equation forward modeling for volcanic rock[J].Geophysical Prospecting for Petroleum,2008,47(4):361-366.
李素华,王云专,卢齐军,等.火山岩波动方程正演模拟研究[J].石油物探,2008,47(4):361-366.
[20]Lv Xiuxiang,Yang Ning,Zhou Xinyuan,et al.Influence of fault activity on Ordovician carbonate reservoir in Tarim Basin[J].Science in China:Series D,2008,38(supplement 1):48-54.
吕修祥,杨宁,周新源,等.塔里木盆地断裂活动对奥陶系碳酸盐岩储层的影响[J].中国科学:D辑,2008,38(增刊1):48-54.
[21]Lv Xiuxiang,Yang Ning,Xie Qilai,et al.Carbonate reservoirs transformed by deep fluid in Tazhong area[J].Oil & Gas Geology,2005,26(3):284-289.
吕修祥,杨宁,解启来,等.塔中地区深部流体对碳酸盐岩储层的改造作用[J].石油与天然气地质,2005,26(3):284-289.
[22]Gong Fuhua,Liu Xiaoping.Controling effects of faults over palaeokarst in west Lungu region,Tarim Basin[J].Carsologica Sinica,2003,22(4):313-317.
龚福华,刘小平.塔里木盆地轮古西地区断裂对奥陶系古岩溶的控制作用[J].中国岩溶,2003,22(4):313-317.
[23]Zhu Guangyou,Yang Haijun,Zhu Yongfeng,et al.Study on petroleum geological characteristics and accumulation of carbonate reservoirs in Hanilcatam area,Tarim Basin[J].Acta Petrologica Sinica,2011,27(3):827-844.
朱光有,杨海军,朱永峰,等.塔里木盆地哈拉哈塘地区碳酸盐岩油气地质特征与富集成藏特征研究[J].岩石学报,2011,27(3):827-844.
[24]Lu Yuhong,Xiao Zhongyao,Gu Qiaoyuan,et al.Geochemical characteristics and accumulation of marine oil and gas in Hanilcatam area,Tarim Basin[J].Science in China:Series D,2007,37(supplement 2):167-176.
卢玉红,肖中尧,顾乔元,等.塔里木盆地环哈拉哈塘海相油气地球化学特征与成藏[J].中国科学:D辑,2007,37(增刊2):167-176.
[25]Mao Xiaoping,He Dawei,Xin Guangzhu,et al.Study of seismic response for thick-layered volcanic rock[J].Oil Geophysical Prospecting,2005,40(6):670-676.
毛小平,何大伟,辛广柱,等.厚层火山岩地震响应研究[J].石油地球物理勘探,2005,40(6):670-676.
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