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伊利石K-Ar/Ar-Ar年龄约束浅地表断层活动时间:原理和潜力 总被引:1,自引:0,他引:1
地壳脆性区断层的定年工作是地质学面临的一个重大瓶颈问题.尽管绝大多数脆性断层在活动时会产生可以用于放射性测年的自生/同运动学伊利石,但同时也会混入影响放射性年龄的碎屑矿物,如2M1多型伊利石或云母,从而使得自生/同运动学伊利石年龄数据受到质疑.随着伊利石年龄分析法及年龄牵引子法的提出,利用分离提纯的各粒级伊利石年龄与颗粒尺度的关系约束近地表脆性断层活动时间的方法逐渐变得可靠.首先介绍了伊利石定年的原理和假设,其次回顾了伊利石年龄限定断层活动时间的研究历史,并总结了关于伊利石年龄数据解释的2种方法及其原理和运用背景.然后评价了影响伊利石定年的可能因素,认为Ar损失在近地表脆性断层域中可以忽略不计,而2M1多型伊利石或云母是否自生对讨论断层泥伊利石年龄的地质意义至关重要.最后指出伊利石定年技术不仅仅局限于浅地表断层定年,还可以约束高应变褶皱及构造混杂岩的变形时间.另外,如果识别俯冲带中与俯冲、增生、剥蚀相关的各构造主控域并分别开展伊利石定年工作,将有助于从时空上对整个俯冲带循环过程(俯冲—增生—剥蚀)的还原. 相似文献
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油气储层自生伊利石分离提纯及其K-Ar 同位素测年技术研究 总被引:4,自引:1,他引:3
油气注入史研究对于指导油气勘探具有非常重要的意义.油气储层自生伊利石K-Ar同位素测年可以为油气注入时间研究提供科学依据.文中对油气储层自生伊利石分离提纯及其K-Ar同位素测年技术进行了系统介绍.碎屑含钾矿物杂质对自生伊利石K-Ar同位素年龄具有非常大的影响,文中对此进行了深入研究,建立了一套完整的数据处理技术并提出了"校正年龄"概念. 相似文献
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为了确定鄂尔多斯盆地苏里格气田的成藏年代,通过提取砂岩储层中的黏土质填隙物,分离分级成 < 0.5、0.5~1.0、1.0~2.0μm的分样品,进行伊利石激光阶段加热40Ar-39Ar定年.等时线年龄是自生伊利石与碎屑伊利石的混合年龄.通过趋势分析和回归分析分别获得极小的趋势年龄和极小的回归年龄,该年龄比较接近自生伊利石年龄.测试结果表明,伊利石的等时线年龄介于160.9~232.0 Ma之间,为自生伊利石与碎屑伊利石的混合年龄.采用数理统计方法获得极小趋势年龄和极小回归年龄分别为151.7 Ma和152.4 Ma,该年龄比较接近自生伊利石年龄,代表了热流体活动和油气成藏时间. 相似文献
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伊利石K—Ar定年法确定油气成藏期研究进展 总被引:7,自引:0,他引:7
自生伊利石的K-Ar定年不仅可以确定成岩期,而且可确定油气成藏期。同时,随着地质演化过程的不同,自生伊利石K-Ar年龄随深度演化会出现不同形式,作者对不同的自生伊利石K-Ar年龄形式及其与油气成期期的关系,进行了探讨性的解释。 相似文献
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伊利石测年在焉耆盆地油气成藏时期研究中的应用 总被引:1,自引:0,他引:1
油气藏成藏时期的确定是进行油气藏勘探与评价的重要工作内容之一。也是揭示成藏过程的有效途径,利用伊利石测年确定油气成藏期,能够得出其绝对年龄,因而受到人们重视,运用自生伊利石同位素年龄测定的原理和方法及自生伊利石同位素年龄资料对焉耆盆地博湖坳陷油气藏成藏时期及油气运移时期进行了分析,最后对自生伊利石同位素测年存在的问题和措施进行了有益的探讨并克服了以往只能根据地质综合研究定性确定油气藏成藏时期及油气运移时期问题,为定量确定油气藏成藏时期以及油气运移时期提供了科学的方法。 相似文献
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油气成藏年代学是新兴的学科发展方向。烃类充注之后,砂岩储层中自生伊利石停止生长,故可利用自生伊利石的年龄来推断储集层中油气藏形成的最老年龄。砂岩样品中存在的有机质在质谱仪离子源中产生的覆盖40Ar峰的有机碎片离子m/e36-m/e40将导致错误的同位素分析和年龄谱结果。经预处理后的伊利石样品加热后在质谱仪离子源中确实产生了有机碎片离子m/e36-m/e44,为获得可靠的分析结果,必须完全清除有机杂质气体。在攻克了有机杂质气体纯化技术之后,笔者开展了珠江口盆地惠州凹陷内3个富油气二级构造带油气藏砂岩自生伊利石40Ar-39Ar法定年研究,采取样品清洗、循环冷冻—加热法破碎样品、经苯-甲醇混合试剂洗油、采用离心机分离粘土矿物。自生伊利石激光阶段加热40Ar-39Ar定年最初低温阶段综合年龄结果表明,惠州凹陷珠海组和珠江组自生伊利石加权平均年龄分别为(12.1±1.1)Ma和(9.9±1.2)Ma,惠州凹陷新近系油气成藏关键时间为10Ma左右。结合该区断裂发育史、油气成藏组合和流体包裹体均一化温度等资料进一步分析认为,中中新世末—晚中新世末的晚期断层活化加强了新近系油气的成藏。 相似文献
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自生伊利石40Ar/39Ar法定年技术及气藏成藏期的确定 总被引:19,自引:1,他引:18
为了确定天然气藏的成藏期,进行了自生伊利石的^40Ar/^39Ar法同位素定年实验.实验重点解决了自生伊利石的^40Ar/^39Ar法定年的几个技术难题:第一,粘土矿物的提纯,避免伊利石以外的含K矿物混入;第二,自生伊利石与碎屑伊利石的分离;第三,克服核反冲造成的Ar原子丢失.利用冷冻一加热循环碎样技术获得高纯度的粘土矿物;通过阶段加热得到的年龄谱可以区分自生伊利石与碎屑伊利石;利用“显微包裹”技术有效克服了核照射反冲问题.对鄂尔多斯盆地北部苏里格气田研究发现。二叠系储层中的伊利石有2种年龄图谱:一种只有自生伊利石的坪年龄;另一种图谱既有自生伊利石的坪年龄,也有碎屑伊利石的年龄,形成二阶式的图谱.通过自生伊利石的形成时间推断,天然气的最早充注时间晚于169~189Ma.实验的结果表明,冷冻加热循环碎样技术可以有效地避免伊利石以外的含K矿物混入.是获得高纯度粘土矿物的关键技术;自生伊利石^40Ar/^39Ar法定年技术可以用于确定天然气藏的成藏期. 相似文献
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Inclined K–Ar illite age spectra in brittle fault gouges: effects of fault reactivation and wall‐rock contamination 
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下载免费PDF全文 K–Ar clay fraction ages of brittle faults often vary with grain size, decreasing in the finer size fractions, producing an inclined age–grain‐size spectrum. K–Ar ages and mineralogical characterization of gouges from two normal faults in the Kongsberg silver mines, southern Norway, suggest that inclined spectra derived from brittle fault rocks reflect the mixing of inherited components with authigenic mineral phases. The ages of the coarsest and finest fractions constrain faulting at c. 260–270 Ma and reactivation around 200–210 Ma, respectively. This study demonstrates how wall‐rock contamination influences the K–Ar age of the coarsest size fractions and that authigenic illite and K‐feldspar can crystallize synkinematically under equivalent conditions and thus yield the same K–Ar ages. 相似文献
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BUI Hoang B NGO Xuan Thanh Yungoo SONG Tetsumaru ITAYA Koshi YAGI KHUONG The Hung NGUYEN Tien Dung 《《地质学报》英文版》2016,90(5):1653-1663
Constraining the timing of fault zone formation is fundamentally important in terms of geotectonics to understand structural evolution and brittle fault processes.This paper presents the first authigenic illite K-Ar age data from fault gouge samples collected from the Red River Shear Zone at Lao Cai province,Vietnam.The fault gouge samples were separated into three grain-size fractions(0.1 μm,0.1-0.4 μm and 0.4-1.0 μm).The results show that the K-Ar age values decrease from coarser to finer grain fractions(24.1 to 19.2 Ma),suggesting enrichment in finer fraction of morerecently grown authigenic illites.The timing of the fault movement are the lower intercept ages at 0%detrital illite(19.2 ± 0.92 Ma and 19.4 ± 0.49 Ma).In combination with previous geochronological data,this result indicates that the metamorphism of the Day Nui Con Voi(DNCV) metamorphic complex took place before ca.26.8 Ma.At about 26.8 Ma-25 Ma,the fault strongly acted to cause the rapid exhumation of the rocks along the Red River-Ailoa Shan Fault Zone(RR-ASFZ).During brittle deformation,the DNCV slowly uplifted,implying weak movement of the fault.This brittle deformation might have lasted for ca.5 Ma. 相似文献
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K‐Ar ages of authigenic illite from two drill‐core gouge samples of a fault in the Palaeoproterozoic basement of Finland record two distinct faulting events. The older sample yields apparent ages from 1240 ± 26 to 1006 ± 21 Ma for four grain size fractions between 6 and <0.1 μm. The second sample is structurally younger and yields statistically distinct ages ranging from 978 ± 20 to 886 ± 18 Ma. We interpret the ages of the <0.1 m fractions, which are the youngest, as representing the actual time of faulting. XRD analysis and age modelling exclude significant age contamination of the finest dated fractions with inherited host rock components. These results provide therefore an example of meaningful isotopic dating of illite‐type clay material formed during Precambrian faulting, demonstrate and constrain fault reactivation and give evidence for brittle Sveconorwegian Mesoproterozoic shortening and Neoproterozoic extension in Fennoscandia. 相似文献
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K-Ar dating of synkinematic illite is increasingly recognized as a central method to constrain the timing of shallow crustal faulting. Methods of efficient sample preparation and quantitative identification of illite polytypes are critical to acquiring K-Ar isotope data for authigenic clays. In this respect, we compared the commonly used clay size separation method through centrifugation with vacuum filtration technology, showing that the former is prone to extract fractions with finer particle ... 相似文献
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伊利石是一种层状硅酸盐矿物,层间主要为钾离子,可利用K-Ar法、Ar-Ar法和Rb-Sr法等相关的测年方法来分析和限定与自生伊利石有关的地质事件的时代,例如盆地演化历史、热液活动、构造活动和油气运移。本文讨论了利用钾盐矿床中自生伊利石进行蒸发岩地层年代学研究的可能性。虽然多数研究表明温度是控制自生伊利石形成的主要控制因素,即自生伊利石一般形成于温度较高的条件下,但一些研究表明在地表温度的盐湖环境中也可形成自生伊利石,此种环境下控制自生伊利石形成的主要因素为流体成分。这构成了利用自生伊利石定年来研究蒸发岩地层时代的理论基础。然而在实际研究过程中仍存在很多问题,需进行进一步的研究。 相似文献
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《Journal of Structural Geology》1999,21(8-9):1039-1048
Clays are a common component of fault gouge, but their genesis and importance in fault evolution is poorly understood. We present preliminary evidence that clays participate in extensive mineral reactions and microfabric changes during faulting. Rather than thinking of clay reactions as a consequence of mechanical processes or fault localization following diagenetically altered horizons, we see the interplay between clay mineral reactions and mechanical processes as a single, integrated process. Furthermore, faulting may lower kinetic barriers to low-temperature (∼100°C) mineral reactions that are common in sedimentary rocks.Our most striking example of fault diagenesis-deformation is a profile of %illite in mixed-layer illite/smectite in shales beneath the Lewis Thrust, Canada. Whereas burial diagenesis caused minimal smectite-to-illite reaction, shales within meters of the thrust are almost completely converted to illite. The consequences of these changes are manifested in geochemical, geochronologic and microfabric characteristics of clay gouge. In this example, faulting has helped overcome a kinetic barrier in the smectite-to-illite reaction without appreciable addition of heat. In another example we infer that dissolution–precipitation reactions continue during faulting even when smectite has already been completely transformed to illite.If mineral reactions intimately interact with mechanical processes in shallow-crustal faults, then our current understanding of the mechanical and hydraulic properties of fault zones may be incomplete. Syndeformational mineral reactions and associated fabric changes could make faults much weaker than would be expected from evaluation of the static mineral assemblage of gouge and single crystal properties. Syndeformational mineral reactions may promote fault slip (affecting earthquake activity) in gouge-bearing faults under stress conditions considerably lower than predicted from static mineral properties. In addition, fault-induced dissolution-precipitation reactions may contribute to fault localization. 相似文献
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西秦岭北缘断裂带漳县—车厂断层的结构及构造演化 总被引:2,自引:0,他引:2
西秦岭北缘断裂带是青藏高原东北缘主要构造边界断裂带之一, 其构造变形历史和运动学特征研究可以为西秦岭中新生代构造过程和印度—亚洲板块碰撞动力学的远程构造响应提供约束。漳县—车厂断层是西秦岭北缘断裂带的重要组成部分, 通过对工程开挖所揭露的断层带内丰富构造现象的观测与分析, 至少可以辨别出3期性质、规模、运动学特征各异的构造变形事件。第一期为向北北东陡倾的伸展正断层作用; 第二期为向南南西倾的由南向北的逆冲断层作用; 第三期为沿近直立断面左旋走滑作用。尽管每期变形的时代尚缺乏构造物质测年的约束, 但根据其与白垩系、新近系的空间关系以及已有第四纪以来沿断层地貌位错和相关沉积物测年以及地震活动历史研究对断层左旋走滑作用的时代约束, 认为第一期伸展正断层作用起始于早白垩纪, 可能持续到渐新世; 第二期向北逆冲断层作用起始于渐新世初, 可能持续到早第四纪; 第三期左旋走滑断层作用起始于晚第四纪, 持续至今。漳县—车厂断层是一条典型的多期变形的脆性断层, 其变形特征与历史, 如果代表了西秦岭北缘断裂带特征与构造变形过程, 那么现今西秦岭北缘断裂带仅是起始于早白垩纪、新生的脆性断裂带, 并非是印支主造山期大规模韧性逆冲推覆作用的边界断层。 相似文献