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1.
显生宙以来,碳酸盐岩地层中有燧石结核产出的现象十分普遍。现有研究认为,硅质生物壳体是燧石结核最主要的硅质来源,随着地质历史上主要硅质生物类型的演变,燧石结核的产出环境逐渐从浅水变为深水。不同地区不同层位的燧石结核往往具有一些共同特征,包括呈孤立分散的结核状产出、硅质选择性交代方解石颗粒而保留晶形完好的白云石、硅质矿物具有隐晶硅质-微晶石英-粗晶石英的规律性变化等。基于上述主要特征及不同研究实例的特点,前人总结出了有机质氧化模式、半透膜模式、混合水硅化模式、重结晶应力控制交代模式等燧石结核成因模式,从不同角度对燧石结核的典型特征进行了解释。然而由于燧石结核成因的复杂性及其可形成于沉积-成岩的不同阶段,各个成因模式均存在一定的局限性,只可用于解释部分地质特征。鉴于燧石结核对研究区的沉积环境、成岩历史等具有很好的指示作用,对其成因的研究具有重要意义,尽管上述模式的提出时间较早,但针对特定问题的研究非常深入,在以后的研究中应加以借鉴。 相似文献
2.
华南地区栖霞组“菊花石”假象与海泡石矿成因关系探讨 总被引:1,自引:0,他引:1
根据对华南地区二叠系栖霞组内菊花石假象的成因研究,结合对该组内燧石结核,菊花石内正延性玉髓和海泡石形成时代关系的现状关系的观察,认为华南地区栖霞组内的海泡石形成于早期成岩作用过程中,与该组内燧石结核和菊花石假象内的正延性玉髓同期形成,其成因既与高盐度的沉积环境或高盐度的成岩环境条件无关,也与热液活动无关。 相似文献
3.
华南地区栖霞组菊花状天青石的交代及其地质意义 总被引:4,自引:0,他引:4
本文在收集大量菊花石标本的基础上,通过岩石薄片镜下鉴定及X射线衍射分析,识别了华南地区栖霞组菊花石假象内矿物的成因类型,建立了矿物交代序列,并通过对菊花石假象内各种矿物成分的电子探针分析和对交代方解石,脉方解石及其围岩的氧,碳同位素分析,探讨了菊花石交代过程中的成岩环境,合理地解释了菊花石内正延性玉髓和栖霞组内海泡石的成因。 相似文献
4.
华南栖霞组菊花石假象内正延性玉髓的成因及其地质意义 总被引:1,自引:2,他引:1
正延性玉髓常被视为干旱蒸发沉积环境的标志。正延性玉髓亦广泛分布于华南地区栖霞组菊花石 (目前绝大多数为天青石假象 )内。本文在天青石后期矿物交代序列识别的基础上,通过对菊花石内各期次碳酸盐交代矿物的电子探针分析,发现菊花石内正延性玉髓形成于富含硫酸根离子和镁离子的成岩介质条件中。结合已有的正延性玉髓研究报道和栖霞组的沉积、成岩作用环境特征分析,认为华南地区栖霞组菊花石内正延性玉髓的形成环境与高蒸发沉积环境或高盐度成岩环境无关。因此,仅根据正延性玉髓的出现不足以确定沉积或成岩环境的盐度条件。 相似文献
5.
北京地区中元古界雾迷山组主要由燧石条带白云岩、燧石结核白云岩、叠层石白云岩和少量含陆源粉砂质碎屑的白云岩组成,广泛出露于北京山区,厚度2000~3500 m。以雾迷山组为代表的大量中元古代硅质沉积物的物源和形成原因,一般教科书均认为层状燧石为生物成因,结核状燧石为成岩交代成因。笔者等在北京西山等地多次野外考察发现,剖面上的硅质条带或硅质结核(下一般称燧石席或硅胶席)。 燧石席内部常包裹或胶结有下伏白云岩的砾石并且因混有有机质等,表现为各种暗色或杂色。硅胶席在上覆白云质沉积物堆积之前与其周围的白云质灰泥和粒屑几乎同时形成,燧石透镜体与白云质沉积物之间存在着相互穿插、包裹的关系,但彼此之间边界清晰,无论是白云石粒屑还是硅胶席都没有任何被交代痕迹。因此,笔者等认为:燧石“结核”是硅胶聚集成席,再经压实、固化的结果,其浑圆状边缘是水下硅胶与沉积介质的相变面。硅胶固化作用是雾迷山组中原生燧石的唯一成因。在成岩重力压实过程中,连续分布的原生硅质沉积物会形成布丁或“结核”构造。白云质灰泥和粒屑的胶结速度与硅胶的固化速度之间存在着明显的差异,遇地震等外力作用,软的硅胶席会沿着弱固结的白云岩裂隙向上侵入或向下挤入,形成硅质脉。遇有后期的岩浆侵入或热变质作用的改造,硅质条带和硅质结核的成分和颜色会发生相应的变化,质地变纯,颜色由深变浅,但是仍然保留原生的层理或纹理,容易被误认为是成岩期或成岩后硅质交代碳酸盐矿物而成。 相似文献
6.
安徽省巢湖地区中二叠统栖霞组以发育一套滨海沼泽-浅海碳酸盐台地环境为主的细碎屑岩至碳酸盐岩沉积建造为特征,灰岩中常见结核状及条带状燧石。燧石多为椭球状和串珠状,部分燧石与灰岩间发育宽约0.5 cm的过渡带。镜下观察灰岩为微晶生物碎屑灰岩;过渡带也多由微晶方解石组成,多数钙质生物壳体被石英充填或半充填,扫描电镜下可见方解石微溶、石英充填溶孔的现象;燧石主要为隐晶及微晶石英,生物碎屑类型与灰岩中基本一致,且多被石英交代。岩石学特征表明死亡的生物在腐烂降解过程中形成的有机酸抑制了碳酸钙的沉淀,并使部分生物碎屑及灰泥发生溶蚀,胶质二氧化硅沉淀,形成燧石结核。燧石中w(Al)/w(Al+Fe+Mn)平均值为0.63,远大于热水沉积硅质岩的最大值0.35;Fe/Ti平均值为9.5,小于热水成因的最小值20;Al-Fe-Mn三角图投点位于非热液成因区域;燧石中Al2O3含量平均值为0.20%,远高于MgO、Na2O、K2O的含量。分析认为,该区燧石结核的二氧化硅可能来源于陆源物质。 相似文献
7.
北京地区中元古界雾迷山组主要由燧石条带白云岩、燧石结核白云岩、叠层石白云岩和少量含陆源粉砂质碎屑的白云岩组成,广泛出露于北京山区,厚度2000~3500 m。以雾迷山组为代表的大量中元古代硅质沉积物的物源和形成原因,一般教科书均认为层状燧石为生物成因,结核状燧石为成岩交代成因。笔者等在北京西山等地多次野外考察发现,二维剖面上的硅质条带或硅质结核在三维实体上实际上是透镜状或席状(下一般称燧石席或硅胶席)。 燧石席内部常包裹或胶结有下伏白云岩的砾石并且因混有有机质等,表现为各种暗色或杂色。硅胶席在上覆白云质沉积物堆积之前与其周围的白云质灰泥和粒屑几乎同时形成,燧石透镜体与白云质沉积物之间存在着相互穿插、包裹的关系,但彼此之间边界清晰,无论是白云石粒屑还是燧石席都没有任何被交代痕迹。因此,笔者等认为:燧石“结核”是硅胶聚集成席,再经压实、固化的结果,其浑圆状边缘是水下硅胶与沉积介质的相变面。硅胶固化作用是北京西山中元古界雾迷山组中原生燧石的唯一成因。在成岩重力压实过程中,连续分布的原生硅质沉积物会形成布丁或“结核”构造。白云质灰泥和粒屑的胶结速度明显快于硅胶的固化速度,遇地震等外力作用,软的硅胶席会沿着弱固结的白云岩裂隙向上侵入或向下挤入,形成硅质脉。遇有后期的岩浆侵入或热变质作用的改造,硅质条带和硅质结核的成分和颜色会发生相应的变化,质地变纯,颜色由深变浅,但是仍然保留原生的层理或纹理,容易被误认为是成岩期或成岩后硅质交代碳酸盐矿物而成。 相似文献
8.
9.
《矿产与地质》2020,(1)
在野外地质调查的基础上,对下扬子巢湖地区二叠系栖霞组硅质结核地球化学特征进行了系统的分析。结果表明:下扬子巢湖地区二叠系栖霞组硅质结核核w(SiO2)为73.50%~96.95%(平均值为85.84%),其他元素含量较低。在主量元素的判别上,硅质成因为生物质成因;在Ti/V-V/Y判别图解中,巢湖地区栖霞组硅质结核来源于洋中脊与大洋盆地端元区域;在元素氧化还原关系上,硅质结核显示出有氧、贫氧与厌氧混合状态;在稀土元素配分图解中,显示出中稀土元素富集,稀土元素总量与P2O5具有很好的相关性和Ce的负异常。在此基础上,结合二叠纪全球气候与海陆位置及洋流的关系,认为下扬子巢湖地区二叠系栖霞组硅质结核是在二叠纪全球气候转变的背景下,在洋流的作用下,来源于大洋中脊与大洋盆地的硅质被大陆边缘的硅质生物捕获而形成硅质结核,洋流作用在硅质结核的形成上起到关键作用。 相似文献
10.
华北板块南缘陕西洛南县北部中元古界蓟县系洛南群巡检司组顶部层控玉化硅质岩中,发育似层状硅质玉髓及透镜状燧石,这些燧石及硅质玉髓已经玉化,质细色艳,达到高品级石英岩质玉石级别,已申报为国家宝玉石矿种,并在宝玉石市场崭露头角,显示出巨大的经济开发潜力。作者以岩石学及地球化学分析为手段,研究该层控玉化硅质岩特征、成因及意义。研究表明: (1)层控玉化硅质岩赋存于中元古界蓟县系洛南群巡检司组顶部的紫红色、灰绿色薄层状砂泥质板岩层中,层厚一般0.5~4 m;似层状玉髓多呈紫红色、灰绿色、烟灰色和无色等,透镜状燧石多呈紫红色及灰绿色似玛瑙纹圈层状。(2)硅质玉髓主要成分为石英,隐晶、微晶结构,块状构造,质地细腻、坚硬,玻璃光泽,半透明—微透明;其Al/(Al+Fe+Mn)均值为0.62,Zr/Hf均值为34.83,Sr/Ba均值除1个异常点外为0.50,V/Ni均值为0.37,ΣREE均值为5.11,δCe均值为1.02,δEu均值为0.86,LaN/CeN均值为0.85,总体显示淡水沉积环境,硅质来源主要为陆源来源,也有后期热液作用来源的部分加入。(3)似层状硅质玉髓层是由于快速海退引起的淡水淋滤硅化作用形成的海底硬底构造或硅质壳;似玛瑙纹透镜状燧石及彩色似层状硅质玉髓层是由于沉积期及沉积期后成岩作用氧化还原条件变化,及后期热液侵入烘烤引起的紫色与绿色致色矿物或致色元素转变形成;角砾状燧石是由于后期秦岭强烈构造作用,引起似层状硅质玉髓上下岩层因软硬差异而产生的变形破裂作用形成的构造角砾岩。 相似文献
11.
Spectacularly developed lower Eocene chert in the Corones platform carbonates of the Spanish Pyrenees is concentrated within a restricted, brackish-water, laminated ostracod-rich facies, which also contains abundant sponge spicules. The chert occurs as nodular, bedded and mottled varieties, and four petrographic types of quartz are developed: microquartz; length-fast (LF) chalcedony; megaquartz; and microspheres. δ18 O values of chert range from 29·6‰ to 30·9‰ (SMOW), which correspond to a broad isotope rank common for biogenic and diagenetic replacement cherts. Calcian dolomite crystals with high Fe and Na are disseminated within the microquartz and LF-chalcedony, but are absent from the megaquartz and host carbonate. The chert is closely associated with desiccation cracks and with interstratal dewatering structures. Load casts are silicified, and laminae rich in sponge spicules are convoluted. Early cracks related to dewatering are filled by microquartz and quartz cements. Ostracod shells within chert are locally fractured; those in the host carbonate are commonly flattened. Late fractures are filled by LF-chalcedony and megaquartz. There is much evidence for the dissolution of sponge spicules and their calcitization in the carbonate host rock. Silica for the Corones cherts was derived from sponges during early diagenesis and shallow burial. Early mechanical compaction and sediment dewatering played a major role in sponge spicule dissolution, migration of silica-rich fluids and the consequent precipitation of chert. Quartz cements continued to be precipitated into the burial environment. 相似文献
12.
In Upper Jurassic carbonate turbidites of the Betic mountains (southern Spain), chert occurs in three morphologies: bedded chert, nodular chert and mottled chert. The last refers to a weak dispersed and selective silification which gives a speckled appearance to the rock. The three types of chert are formed by replacement of limestones and are associated with different calcareous facies. Turbidite packstones of Saccocoma and peloids, and turbidite lime mudstones of pelagic material contain bedded and nodular cherts. The silicification textures are mainly micro- and cryptocrystalline quartz, with local chalcedonic quartz (both length-fast and length-slow) which is more common in the packstones. Only mottled chert is produced where calcareous breccia beds are silicified. Mottled chert consists of micro- and cryptocrystalline quartz, length-slow chalcedonic quartz and mosaics or individual crystals of euhedral megaquartz. Beds and nodules are the result of early diagenetic silicification, with silica derived from the calcitization and dissolution of radiolarians and, subordinately, sponge spicules, whereas mottled chert is the consequence of later silicification in a probably Mg-rich environment. Early silicification is mainly confined to turbidite beds and only rarely occurs in the interbedded pelagic limestones. Turbidite sedimentation favours silicification because rapid burial of the transported siliceous tests prevents silica from the dissolution of tests passing into overlying sea water. A silica-rich interstitial fluid develops in the turbidite layer and this migrates to more permeable zones giving rise to bedded and nodular chert. 相似文献
13.
Nodular chert from the middle and upper Arbuckle Group (Early Ordovician) in the Slick Hills, SW Oklahoma, was formed by selective replacement of grainstones, burrow fillings, algal structures, and evaporite nodules. Chert nodules are dominantly microquartz with minor fibrous quartz (both quartzine and chalcedony), megaquartz, and microflamboyant quartz. Lepisphere textures of an opal-CT precursor are preserved in many (especially in finely-crystalline) chert nodules. The δ18O values of microquartz chert range from +23.4 to + 28.80/00 (SMOW), significantly lower than those of Cenozoic and Mesozoic microquartz chert formed both in the deep sea and from near-surface sea water. The δ18O values of chert decrease with increasing quartz crystal size. Silicification in the Arbuckle Group occurred during early diagenesis, with the timing constrained by the relative temporal relationships among silicification, burial compaction, and early dolomite stabilization. Silica for initial chert nucleation may have been derived from both dissolution of sponge spicules and silica-enriched sea water. Chert nucleation appears to have been controlled by the porosity, permeability, and organic matter content of precursor sediments. This conclusion is based on the fact that chert selectively replaced both porous grainstones and burrows and algal structures enriched in organic matter. Growth of chert probably occurred by a maturation process from opal-A(?), to opal-CT, to quartz, as indicated by the presence of opal-CT precursor textures in many chert nodules. Although field and petrographic evidence argues for an early marine origin for chert in the Arbuckle Group, the light δ18O values are inconsistent with this origin. Meteoric resetting of the δ18O values of the chert during exposure of the carbonate platform best explains the light δ18O values because: (i) the δ18O values of chert nodules decrease with decreasing δ18O values of host limestones, and (ii) chert nodules from early dolomite, which underwent more extensive meteoric modification than associated limestones, have lighter δ18O values than chert nodules from limestones. Increasing recrystallization of chert nodules by meteoric water resulted in progressive 18O depletion and (quartz) crystal enlargement. 相似文献
14.
Quaternary pedogenic calcretes from the Kalahari (southern Africa): mineralogy, genesis and diagenesis 总被引:2,自引:0,他引:2
N. L. WATTS 《Sedimentology》1980,27(6):661-686
15.
WILLIAM J. MEYERS 《Sedimentology》1977,24(1):75-105
Chert distribution in the Lake Valley rocks is selective to mud-supported facies; it is not related to proximity to unconformities. The facies selectivity of the chertification is believed to be a function of the depositional distribution of indigenous silica as sponge spicules, an interpretation that is supported by high positive qualitative correlation of chert with spiculitic rocks. Petrography indicates that the spicules were all originally siliceous, and that they all went through a moldic stage during which many molds were compactively destroyed and distorted. Remaining molds were subsequently cemented by calcite or chalcedony. Chert distribution and spicule petrography argue for an intraformational source for much of the silica. Chert micro-fabrics are dominated by microquartz, a replacement of grains and lime mud; length-fast chalcedony, a pore-filling cement; and megaquartz, a post-chalcedony pore-filling cement. Petrography of compaction features within chert masses indicates that chertification occurred after some burial. Based on stratigraphic reconstruction this burial depth was a maximum of about 215 m. and was most likely a few metres to a few tens of metres. Petrography of chert-calcite cement relationships indicates that chertification occurred before and during first generation, pre-Pennsylvanian non-ferroan calcite cementation, and was completed before late-stage, post-Mississippian ferroan calcite precipitation. Petrography of chert clasts in basal Rancheria (Meramecian) and basal Pennsylvanian conglomerates proves these clasts derived from the Lake Valley Formation and were chertified before redeposition. Thus, some cherts in the Lake Valley are pre-Meramecian in age, but all are pre-Pennsylvanian in age. Furthermore, association of the cherts with the non-ferroan cements indicates the cherts were probably precipitated in meteoric phreatic lens established beneath the pre-Meramecian and pre-Pennsylvanian subaerial unconformities. 相似文献
16.
Chalcedonic quartz and occurrence of quartzine (length-slow chalcedony) in pelagic sediments 总被引:2,自引:0,他引:2
J. B. KEENE 《Sedimentology》1983,30(3):449-454
ABSTRACT Chalcedony is the most abundant form of quartz in silicified pelagic sediments from the North Pacific. Varieties of chalcedonic quartz present in chert of deep-sea origin include chalcedony (length-fast and zebraic), quartzine (length-slow), and lutecite.
These occurrences of quartzine in known pelagic sediments emphasize the dangers of using quartzine as an indicator of former evaporitic environments. Quartzine is a diagenetic mineral and does indicate pore fluids rich in sulphate and magnesium. In pelagic sediments, it is always associated with authigenic barite and in many cases with authigenic dolomite. Quartzine should not be used, by itself, as an indicator of any particular environment of deposition. 相似文献
These occurrences of quartzine in known pelagic sediments emphasize the dangers of using quartzine as an indicator of former evaporitic environments. Quartzine is a diagenetic mineral and does indicate pore fluids rich in sulphate and magnesium. In pelagic sediments, it is always associated with authigenic barite and in many cases with authigenic dolomite. Quartzine should not be used, by itself, as an indicator of any particular environment of deposition. 相似文献
17.
Environments characterized by fluctuating hypersaline to fresh-water conditions are defined as “schizohaline” and examples are given of situations in which “schizohaline” environments can arise. Fabrics diagnostic for the occurrence of both hyper- and hyposalinity have been recorded in Late Paleozoic rocks from Bear Island (74°30′N, 19°E): evaporite nodules, length-slow chalcedony and very finely crystalline penecontemporaneous dolomite are considered as indicators of hypersaline conditions while euhedral limpid dolomite crystals, coarse poikilitic sparry calcite and microspar calcite are thought to have originated under the hyposaline regime. Zoned dolomite crystals and euhedral crystals of authigenic mega-quartz replacing sulphates have also been recorded in the same rocks; their diagnostic importance for the schizohaline environment is, however, uncertain.Internal structural pores of some crinoid and bryozoan skeletal grains of biosparites from Bear Island are either empty or infilled with very finely crystalline dolomite. Expulsion of Mg2+ ions from the magnesian-calcite skeletons and either: (1) “poisoning” of the micro-environment of the pores; or (2) formation of stagnant “micro-sabkha” conditions in the pores are proposed as an explanation for these phenomena. 相似文献
18.
The Marl Slate, the English equivalent of the Kupferschiefer, has been studied with particular reference to the relationships between dolomitization and the origin of the metal sulphides. Dolomite occurs as: 1) discontinuous lenses of ferroan dolomicrite, 2) micronodules of finely crystalline dolospar in association with length-slow chalcedony and 3) discrete laminae of ferroan or non-ferroan dolospar. The ferroan dolomicrite has excess CaCO3, and is more abundant in the lower, sapropelic facies of the Marl Slate. It is considered to have formed by the penecontemporaneous alteration of calcium carbonate under hypersaline conditions. Small micronodules (typically about 0.3 mm in diameter) are also more abundant in the sapropelic Marl Slate. These frequently contain cores of length-slow chalcedony (quartzine) fibres and sometimes quartz megacrysts. Textural observations clearly indicate that this silica is of authigenic origin and the dolomite/chalcedony micronodules are interpreted as diagenetic replacements of a calcium sulphate mineral such as anhydrite. The discrete laminae of finely crystalline dolospar are often inter-laminated with calcite in the upper part of the Marl Slate. This dolomite is also calcium rich and represents a replacement, possibly of anhydrite, during a later phase of diagenesis. Metal sulphides occur in two distinct forms: as disseminated framboidal pyrite and as discrete lenses of pyrite, chalcopyrite, galena, sphalerite and rarer sulphides. The framboidal pyrite originated during early diagenesis by reaction of sulphide, produced by reduction of sulphate by organic material and micro-organisms, with iron also released in the reducing environment. The sulphide lenses are often in intimate association with dolospar, length-slow chalcedony and authigenic quartz megacrysts. This indicates that the lenses were produced during diagenesis by the reduction and replacement of calcium sulphate (anhydrite). Various sources, such as co-precipitation with dolomite precursors and the underlying Yellow Sands, may have supplied metals which were mobilized and transported by connate brines as diagenesis progressed. 相似文献
19.
The middle Permian Chihsia Formation of south China accumulated on a shallow shelf, and consists mainly of black to dark grey micritic limestone rich in chert nodules and organic matter. A unique type of nodular crystal cluster is distributed widely in the carbonate succession. Most crystal clusters consist of calcite. Some, however, are composed of celestite, and geochemical, microscopic and crystal morphological data suggest that celestite was the precursor of the calcite. The celestite developed displacively within the sediments during early diagenesis, before compaction and before local dolomitization of the host rock. Similar strontium isotopic values were obtained from the celestite clusters, replacement calcite, vein calcite and host rock. The values are within the range of middle Permian sea water. The strontium in the celestite was furnished chiefly by either diagenetic alteration of strontium‐rich marine aragonite to strontium‐poor calcite, or aragonite dissolution induced by aerobic oxidation of organic matter, or both. The sulphur isotopic values of the celestite are about 6–11‰ heavier than the sulphur isotopic value of sulphate in coeval sea water. Based on geological context, this difference is attributed to microbial reduction of porewater sulphate in the Chihsia sediments. 相似文献