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阿尔金山南缘侏罗系页岩气生烃及储集条件 总被引:1,自引:1,他引:0
柴达木盆地阿尔金山南缘侏罗系发育,具备油气生成的条件,但尚未开展页岩气调查评价。通过野外地质测量和样品采集分析,调查了侏罗纪泥页岩发育的厚度、沉积环境,分析了页岩地球化学、储层物性等页岩气地质条件。研究表明,侏罗纪泥页岩累计厚度介于158~250m之间,单层最大厚度89m;沉积环境以深湖-半深湖为主;有机碳含量介于0.15%~7.96%之间,平均2.05%;镜质体反射率介于1.02%~2.50%之间,平均1.41%;有机质类型以Ⅱ1和Ⅱ2型为主;泥页岩微裂缝及微孔隙发育,脆性矿物平均含量大于43%。综合分析认为,阿尔金山南缘侏罗系泥页岩具有较好的页岩气生烃和储集条件,可作为页岩气勘查开发的有利层系。 相似文献
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模拟火山喷气成矿作用,在热硫化条件下,系统考察反应物中铁硫比值从Fe∶S=1∶1至1∶8变化对黄铁矿形成的影响。运用扫描电镜(SEM)、X射线粉晶衍射分析(XRD)等测试手段,观测和分析实验产物的形貌、成分和结构特征,发现随着Fe∶S比值的减小,实验产物中黄铁矿逐渐增多,磁黄铁矿逐渐减少,同时Fe∶S比值对实验产物的形貌也有一定的控制作用。计算结果显示实验产物中黄铁矿晶粒尺寸的变化范围为42.543~63.799 nm,磁黄铁矿晶粒尺寸的变化范围为21.973~87.926 nm,黄铁矿和磁黄铁矿的晶胞体积变化较小。结合热力学计算结果分析认为,在热硫化条件下,当Fe∶S比值小于或等于磁黄铁矿中铁硫原子比时,反应生成磁黄铁矿;当Fe∶S比值超过磁黄铁矿中铁硫原子比时,实验产物中出现黄铁矿;当Fe∶S比值达到或超过黄铁矿中铁硫原子比时,反应主要生成黄铁矿。过硫条件有利于黄铁矿的生长,硫源越充足,实验产物中黄铁矿越多。 相似文献
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鄂西地区震旦系陡山沱组是中国页岩气勘查的新层系,其页岩储层矿物成分以白云石为主,测井响应特征与奥陶系五峰组—志留系龙马溪组、寒武系牛蹄塘组硅质页岩明显不同,原有储层"七性"关系测井评价对于陡山沱组页岩储层精细刻画和压裂施工解释评价存在一定的不适用性。本文以鄂阳页1井为例,综合利用常规测井、特殊测井和样品测试分析资料,研究发现不同于五峰组—龙马溪组和牛蹄塘组硅质页岩"四高四低"测井响应特征,陡山沱组二段云质页岩具有低伽马、低铀、低声波时差、低中子,高电阻率、高密度"四低两高"测井响应特征,认为元素测井是评价陡山沱组二段页岩地层总有机碳含量最直接和有效的方法,MRIL-P型核磁测井适用于该地层孔隙度参数评价。通过拟合计算完善了适用于该地层的含气量估算方法,获取了有利页岩储层评价参数,研究成果将为同类型页岩储层测井评价提供参考依据。 相似文献
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Micropores of shale are significant to the gas content and production potential of shale, which has been verified in the research of marine shale gas; while, few studies have been conducted on lacustrine shales. This study collected 42 samples from three wells in the Late Cretaceous Qingshankou Formation of the southern Songliao Basin, NE China, and investigated these samples by the focused ion beam-scanning electron microscope (FIB–SEM) and nitrogen adsorption analysis techniques. Four types of micropores were identified in the samples, i.e., intergranular pore, intracellular pore, organic matter pore and microfracture. The pore structure type is characterized by open slit pores and “ink type” pores which are mainly 1.5–5 nm in diameter with mesopores as the main pores. The mesopores account for 74.01% of the pore volume and 54.68% of the pore surface area. Compared with the lacustrine shales from the Triassic Yanchang Formation in the Ordos Basin and Xujiahe Formation in the Sichuan Basin, the intergranular clay mineral interlayer pores are considered to be the main reservoir space for shale gas storage in the study area, followed by intraparticle pores, organic matter pores and microfractures. Maturity and micropore are the key controlling factors which affect the shale gas content of the Qingshankou Formation in southern Songliao Basin. 相似文献
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<正>Southern Songliao basin consists of four A structural units from west to east:western slopes,southwest ridge,central depression and southeast uplift.Upper Cretaceous Qingshankou Formation shale sedimented in large-scale invasion of the lake,with a quick settlement,super fast filling compensation deposition characteristics and widely deposition of organic-rich,thick black shale interbedded oil shale,which is the most important source rocks on Songliao basin.The main organic matter types of 相似文献
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青藏高原多年冻土区不同草地类型生态系统呼吸季节差异性 总被引:1,自引:1,他引:0
研究多年冻土区不同草地类型及季节生态系统呼吸,对理解青藏高原碳源汇关系及其对气候变化响应具有重要意义。在青藏高原风火山选取高寒草甸和沼泽草甸对生长季和非生长季生态系统呼吸进行观测。结果表明:生态系统呼吸呈明显的日变化和季节变化,高寒草甸日变异系数(0.30~0.92)高于沼泽草甸(0.12~0.29),高寒草甸非生长季生态系统呼吸白天/晚上比高于生长季,而沼泽草甸季节变化较小;季节变化与5 cm地温变化一致。高寒草甸和沼泽草甸非生长季生态系统呼吸平均速率分别为0.31和0.36 μmol·m-2·s-1,生长季分别为1.99和2.85 μmol·m-2·s-1。沼泽草甸生态系统呼吸年排放总量为1 419.01 gCO2·m-2,显著高于高寒草甸(1 042.99 gCO2·m-2),其中非生长季高27%,生长季高39%。高寒草甸和沼泽草甸非生长季生态系统呼吸总量分别为268.13和340.40 gCO2·m-2,分别占全年的25.71%和23.99%。两种草地类型生态系统呼吸与气温、5 cm和20 cm地温均显著相关,可解释37%~73%的季节变异,除生长季沼泽草甸外,生态系统呼吸与5 cm地温相关性最高。非生长季5 cm地温对应Q10为4.34~5.02,高于生长季(2.35~2.75),且沼泽草甸高于高寒草甸。生长季生态系统呼吸与土壤水分无显著关系,而非生长季生态系统呼吸受土壤水分显著影响(R2:0.21~0.40),随土壤水分增加而增加。 相似文献
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