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A model is presented for the emplacement of intermediate volume ignimbrites based on a study of two 6 km3 volume ignimbrites on Roccamonfina Volcano, Italy. The model considers that the flows were slow moving, and quickly deflated from turbulent to non-turbulent conditions. Yield strength and density increased whereas fluidisation decreased with time and runout of the pyroclastic flows. In proximal locations, on the caldera rim, heterogeneous exposures including discontinuous lithic breccias, stratified and cross-stratified units interbedded with massive ignimbrite suggest deposition from turbulent flows. In medial locations thick, massive ignimbrite occurs associated with three types of co-ignimbrite lithic breccia which we interpret as being emplaced by non-turbulent flows. Multiple grading of different breccia/lithic concentration types within single flow units indicates that internal shear occurred producing overriding or overlapping of the rear of the flow onto the slower-moving front part. This overriding of different parts of non-turbulent pyroclastic flows could be caused by at least two different mechanisms: (1) changes in flow regime, such as hydraulic jumps that may occur at breaks in slope; and (2) periods of increased discharge rate, possibly associated with caldera collapse, producing fresh pulses of lithic-rich material that sheared onto the slower-moving part of the flow in front.We propose that ground surge deposits enriched in pumice compared with their associated ignimbrite probably formed by a flow separation mechanism from the top and front of the pyroclastic flow. These turbulent clouds moved ahead of the non-turbulent lower part of the flow to form stratified pumice-rich deposits. In distal regions well-developed coarse, often clast-supported, pumice concentrations zones and coarse intra-flow-unit lithic concentrations occur within the massive ignimbrite. We suggest that the flows were non-turbulent, possessed a relatively high yield strength and may have moved by plug flow prior to emplacement. 相似文献
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The Trypali carbonate unit (Upper Triassic), which crops out mainly in central‐western Crete, occurs between the parautochthonous series (Plattenkalk or Talea Ori‐Ida series, e.g. metamorphic Ionian series) and the Tripolis nappe (comprising the Tripolis carbonate series and including a basal Phyllite–Quartzite unit). It consists of interbedded dolomitic layers, represented principally by algally laminated peloidal mudstones, foraminiferal, peloidal and ooidal grainstones, as well as by fine‐grained detrital carbonate layers, in which coarse baroque dolomite crystals and dolomite nodules are dispersed. Baroque dolomite is present as pseudomorphs after evaporite crystals (nodules and rosettes), which grew penecontemporaneously by displacement and/or replacement of the host sediments (sabkha diagenesis). However, portions of the evaporites show evidence of resedimentation. Pre‐existing evaporites predominantly consisted of skeletal halite crystals that formed from fragmentation of pyramidal‐shaped hoppers, as well as of anhydrite nodules and rosettes (salt crusts). All microfacies are characteristic of peritidal depositional environments, such as sabkhas, tidal flats, shallow hypersaline lagoons, tidal bars and/or tidal channels. Along most horizons, the Trypali unit is strongly brecciated. These breccias are of solution‐collapse origin, forming after the removal of evaporite beds. Evaporite‐related diagenetic fabrics show that there was extensive dissolution and replacement of pre‐existing evaporites, which resulted in solution‐collapse of the carbonate beds. Evaporite replacement fabrics, including calcitized and silicified evaporite crystals, are present in cements in the carbonate breccias. Brecciation was a multistage process; it started in the Triassic, but was most active in the Tertiary, in association with uplift and ground‐water flow (telogenetic alteration). During late diagenesis, in zones of intense evaporite leaching and brecciation, solution‐collapse breccias were transformed to rauhwackes. The Trypali carbonate breccias (Trypali unit) are lithologically and texturally similar to the Triassic solution‐collapse breccias of the Ionian zone (continental Greece). The evaporites probably represent a major diapiric injection along the base of the parautochthonous series (metamorphic Ionian series) and also along the overthrust surface separating the parautochthonous series from the Tripolis nappe (Phyllite–Quartzite and Tripolis series). The injected evaporites were subsequently transformed into solution‐collapse breccias. 相似文献
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从宏观基础地质入手,按矿床学的一些基本概念,针对东川-易门铜矿床地质地球化学特征,探讨了一些存在争议的重要问题。研究认为:狮山段是绿汁江组下部独立存在的地层层位;东川-易门式铜矿床属沉积-改造成因,其中的层状铜矿属沉积成岩成因,不是"热液成矿";所谓东川-易门式矿床(稀矿山除外)为"喷流沉积成矿"或"岩浆叠加",尚依据不足;刺穿体是构造作用产物,对成矿有利,是良好的找矿标志,其中的角砾岩主要是沉积角砾岩与构造角砾岩,或沉积-构造角砾岩,不足以冠名"隐爆角砾岩(筒)"。 相似文献
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震裂锥已被公认为陨石冲击地球表面遗留的标志。研究及统计资料表明,震裂锥与陨石冲击形成的中、大型冲击坑
有关。太湖西山震裂锥呈圆锥形,锥体表面有自锥顶向下辐射的锥纹,锥纹具有分叉的特征,这些特征与震裂锥的国际公
认的定义和标准相符。此外,西山震裂锥还具有其特有的其他特征:碎裂岩化显著;气化-熔融现象发育;锥体表面具网
状构造及波纹状、蜂窝状等多种气印。岩相学研究显示,震裂锥及含锥岩石中冲击变质现象明显,微页理(PDFs)、微裂
隙(PFs) 以及靶岩熔融现象发育。以上这些冲击变质的标志,可证明西山震裂锥是冲击成因,而非地表水风化淋溶石灰岩
的喀斯特或风蚀成因的凤稜石。西山震裂锥的发现、太湖湖底冲击击变角砾岩“太湖石”的确定,为太湖冲击坑的研究增
添了新的诊断性证据;加上早期研究确定的、冲击回落至太湖湖底淤泥层中的冲击溅射物,这些众多证据为确定“太湖冲
击坑”或“太湖冲击事件”展示了美好前景。但是,要确定太湖冲击坑的具体位置、大小及构造模式等,尚需更多的深入
研究。 相似文献
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论湖南石门雄黄矿区矿化角砾岩成因类型 总被引:4,自引:0,他引:4
湖南石门界牌峪地区雄黄矿床中伴有各类化角砾岩。它们互不相连,外观圆形,有的聚集成群或呈完全弧立的山包,与围岩多呈刺穿状接触,角砾岩胶结物中微量元素同该区现代热泉体系沉积物类似,成矿溶液和角砾岩胶结物包裹体成分富Na^+,Ca^2+,Cl^-,HCO^-3和SO62-4,也与该区现代热泉水成分相似。 相似文献
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梁定益等(2002)研究认为太行山北段河北省涞源县白石山地质公园内存在一条与中元古代雾迷山组沉积时代相当的地裂缝构造,且地裂缝内填充由地震触发,重力垮塌形成的震积岩(含软沉积变形)。近期实地考察后,笔者等得出与上述观点不同的认识,即先前认为的地裂缝实为一条断裂带:震积岩为断裂带构造岩;断层主滑移带内发育S—C面理构造;断层角砾复杂结构是构造变形和压溶作用的结果;断裂整体表现为含正断层分量的走滑断层。结合太行山北段区域构造演化历史,本文提出该断裂最早形成于燕山运动期间,此后在区域构造应力作用下可能多次活动。 相似文献
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方维萱 《大地构造与成矿学》2016,(2):237-265
含矿热液角砾岩类和非含矿角砾岩类的成岩成矿机制、独立填图单元确定和构造岩相学填图等问题,一直是困惑地质学家的难题。有效解决这些难题,对于研究和恢复矿田构造具有重要价值。在热液角砾岩成岩成矿系统中,热液角砾岩类不但是流体–岩石的多期次地球化学耦合与叠加作用、强烈流体交代作用的物理–化学反应库,也是各类叠加地质作用过程和结果的构造岩相学物质记录。因此,对其深入研究有助于提升成岩成矿系统理论认识水平。在综述以往研究基础上,本文提出了热液角砾岩构造系统概念、研究内容、研究方法和技术组合。在对角砾岩相系分类基础上,针对热液角砾岩相系的复杂性,通过岩相学填图实例解剖,总结专项填图中构造岩相学填图单元建立方法和填图技术,探索采用岩相学填图恢复热液角砾岩构造系统的新方法及技术组合。通过专项研究认为热液角砾岩系统主要形成有利的构造地质背景有:(1)复式侵入岩体在多期次岩浆侵入过程中,岩浆结晶分异和不混溶作用、岩浆冷却与围岩–先存构造多重耦合过程、同岩浆侵入期的脆韧性剪切带耦合、侵入岩体在后期构造–流体叠加过程等,对于形成热液角砾岩构造系统有利;(2)在火山岩相系中,早期次火山侵入体、晚期次火山岩侵入体和后期岩浆侵入岩体等,对于形成热液角砾岩体构造系统十分有利;(3)在沉积盆地后期叠加改造过程中,先存火山角砾岩、岩溶角砾岩和沉积角砾岩相系等,在后期盆地流体注入和多期次岩浆侵入过程中,有利于形成叠加热液角砾岩体构造系统;(4)在多期次的构造–岩浆–角砾岩杂岩带中,有利于形成热液角砾岩构造系统。研究认为多期次岩浆侵入体、火山–次火山岩侵入体和盆地中热流体是形成热液角砾岩构造系统的主要机制,包括与多期次复式侵入体有关的岩浆热液角砾岩构造系统、火山–次火山热液角砾岩构造系统、构造热液角砾岩构造系统和复合热液角砾岩系统等,它们均属矿田构造类型,也是多矿种共生矿床的成岩成矿机制。采用构造岩相学专项填图技术,对不同类型热液角砾岩构造系统及成岩成矿中心进行重建,有助于寻找和发现深部隐蔽构造和隐伏铁氧化物铜金型(IOCG)矿床找矿预测。 相似文献
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新疆东准噶尔石炭纪火山机构类型与时限 总被引:10,自引:2,他引:8
东准噶尔卡拉麦里大气田的主要储层是石炭纪火山岩,石炭纪古火山机构的样式与组合特征,与火山岩储层展布关系密切。野外调查表明,隐爆角砾岩是东准噶尔石炭纪古火山机构最常见的标志之一。东准噶尔石炭纪古火山机构类型主要有中心式、裂隙式和裂隙-中心式等样式。中心式火山机构以大石头层状火山、柯克巴斯套锥状火山最为典型;巴塔玛依内山附近沿断裂分布的带状火山岩具有裂隙式喷发的特征;东黑山火山具有火山口串珠状排列特征,是裂隙-中心式喷发的产物。大石头地区原缪林托凯陶山组火山岩的锆石SHRIMP U-Pb年龄为345.6±7.1 Ma,而已知巴塔玛依内山组火山岩年龄是350.0±6.3Ma,因此东准噶尔火山活动的主要时期是早石炭世。 相似文献