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二叠纪—三叠纪生物大灭绝导致大量生物死亡及生态系统的严重破坏,早三叠世全球变暖[1-4]、海水多次酸化[5-7]、风化速率[8-12]及海洋沉积速率突增[13]等多个事件共存。在这一紊乱的时期,作为碳酸盐岩组分的鲕粒广泛发育于全球下三叠统地层[14-16],且因出现巨型鲕粒而受到广泛关注。作为一种指相颗粒,鲕粒可通过原始矿物、圈层特征、形态特征、以及鲕粒组合特征指示古海洋条件,如水动力、水深、盐度、气候条件以及敏感的水化学条件等[17-22]。直径作为其最直观的特征,常与水动力条件及海水碳酸盐饱和度相联系。在鲕粒形成过程中物理环境与海水化学一样重要[23-26]。鲕粒大小反映快速沉淀和磨损率之间的动态平衡[18],与流速直接相关[27-29],直径大表示更强的水动力条件[30-31]。相对于鲕粒总寿命[32],鲕粒快速达到动态平衡大小,而后大小和形状基本保持不变。研究发现早三叠世全球鲕粒和巨鲕的出现与富氧/缺氧及碳同位素扰动有很强的对应关系,是生物大灭绝的沉积响应,鲕粒的大小可能是一个量化生态系统破坏程度的沉积指标,巨鲕的出现可能代表遭受比其他地区更高的生态系统压力[14,23]。Li et al.[33]通过建立鲕粒直径数据约束下的鲕粒生长物理化学模型定量的分析了早三叠世海水化学,得出早三叠世碳酸盐饱和度可能达到现代的7倍,且pH值也大幅下降。因此对鲕粒粒度的精细研究,对恢复这一时期复杂的古环境具有重要意义。四川东北部下三叠统飞仙关组鲕粒滩非均质性强、沉积结构复杂,前人已进行了大量研究,但对鲕粒类型的细分、鲕粒类型的时空演化及鲕粒类型与水动力条件(粒度)的相关性还需进一步的精细研究。因此本文选取川东北莱溪、龙潭村及鱼洞子飞仙关组剖面,通过野外实测、镜下鉴定及粒度分析方法对其进行研究。
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早三叠世,上扬子地区位于东特提斯,飞仙关组鲕粒发育与同时期全球热带—亚热带浅水台地鲕粒沉积相对应[14,23](图1a)。研究剖面位于上扬子地区开江—梁平海槽西侧,海槽的形成受南秦岭洋的扩张与收缩、“峨眉地裂”运动的影响,受海平面下降及沉积速率加快的共同影响而消亡于飞仙关期。开江—梁平海槽西侧发育正常碳酸盐岩台地,东侧与城口—鄂西海槽之间则具有孤立台地性质[34-40]。鲕粒主要发育于开江—梁平海槽两侧以及城口—鄂西海槽西部台缘鲕粒滩(图1b),少量形成于台内点滩[41-45]。开江—鄂西海槽西侧为迁移型,白云石化作用弱,滩体厚度薄但明显向东迁移;东侧为加积型,白云石化作用强烈,鲕粒滩厚度大。鲕粒滩发育主要受海平面变化、古构造、古风向及差异沉降影响[41,46-49]。由于早三叠世处于“文石海”时期,文石优先沉淀,稳定性较差,后期常被成岩改造为稳定的低镁方解石或白云石。莱溪、龙潭村及鱼洞子剖面位于开江—鄂西海槽西侧,飞仙关早期台缘鲕粒滩发育,鱼洞子剖面位于鲕粒滩主体区,莱溪及龙潭村位于鲕粒滩边缘带。研究剖面白云石化作用较弱,可减小鲕粒原始空间尺寸被白云石化作用期间潜在的尺寸再生影响[50-51],从而提高本次研究的准确性。
图 1 早三叠世全球鲕粒发育区及研究区飞仙关早期沉积相平面展布
Figure 1. Lower Triassic global ooids development and sedimentary facies distribution in the study area during the early Feixianguan period
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实测莱溪、龙潭村及鱼洞子剖面,根据岩性、沉积结构及构造划分层位,对鲕粒发育层位重点取样。对岩石样品进行磨片并使用茜素红染色,在偏光显微镜下对鲕粒进行识别划分。鲕粒粒度分析则利用徕卡偏光显微镜及川大图像分析系统软件对莱溪22张、龙潭村29张及鱼洞子58张鲕粒发育薄片进行镜下鲕粒粒度测量。为了减小误差,对粒度较大的鲕粒使用2倍物镜,10倍目镜,选取最能代表样品鲕粒发育特征的3~5个视域进行测量。粒度较小的鲕粒使用4倍物镜,10倍目镜进行测量,每个样品测量鲕粒数至少100。对所测得的鲕粒粒径D使用Φ=-log2D进行转化得到转化值Φ′,因为所测得值为镜下值,所以再对Φ′使用弗里德公式Φ=0.902 7Φ′+0.381 5进行校正[52]。最后利用所得Φ值进行计算得到鲕粒样品的平均粒径、标准偏差、偏度及峰度等粒度参数,并绘制直方图、频率曲线以及概率累计曲线对粒度资料进行图解[53]。
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鲕粒受沉积环境的影响而呈现出不同形态,在已有研究的基础上[18,30,54-56],综合考虑鲕粒成因、原始矿物、圈层结构、形态特征及成岩作用改造等多方面因素,将研究区内鲕粒划分为原生沉积的藻鲕、同心鲕、表鲕、复鲕、椭形鲕、巨鲕、偏心鲕及后生改造的泥晶鲕、偏心鲕、变形鲕、负鲕、单晶鲕、多晶鲕、白云化鲕、残余鲕、破碎鲕(图2)。研究发现偏心鲕在原生沉积及后生改造中都可形成,应结合其组成矿物及圈层形态进行识别。破碎鲕可根据破碎形态进一步划分为断壳鲕、破裂鲕、错裂鲕及残缺鲕。
图 2 鲕粒类型划分方案
Figure 2. Classification scheme of ooid types
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研究区内藻鲕仅少量发育,形态常受控于核心,鲕粒边界微起伏,鲕粒边部颜色较深(图3a),部分受海水纤状环边胶结及大气淡水胶结(图3b)。同心鲕粒径较大,0.5~2 mm,鲕粒圈层结构明显(图3c),可见栉壳状胶结及等粒状大气淡水胶结,部分圈层或核受大气淡水选择性溶蚀再沉淀形成较粗晶粒(图3d)。同心鲕重结晶作用受圈层结构限制,而形成明暗相间的圈层(图3e)。表鲕的粒径变化较大,其形成受水动力及核大小的影响,因此表鲕发育层位不能简单的认为水动力小,而需要从鲕粒组合及表鲕核心大小等多方面来分析判断(图3f)。复鲕由两个或多个鲕粒组成一个新的核心,被外部大的包壳所包围形成,颗粒间灰泥充填,外部包壳最内层可变厚度,这可能是由核心内部颗粒之间的间隙确定的(图3g,h)。椭形鲕受不规则核心形状控制(图3i),同沉积的其他类型鲕粒为球形。研究区巨鲕粒径可达10 mm,相比于其他鲕粒其核心更大(图3j),同心圈层发育,颗粒间灰泥填充,部分圈层及基质重结晶(图3k)。已有研究表明,其异常的粒径可能是由于早三叠世大部分骨骼生物灭绝而导致的核心供应减少、微生物的积极参与及海水碳酸盐饱和度的快速增加形成[33,57-64],该地区此时可能遭受很高的生态系统压力[14]。原生成因的偏心鲕同心层不对称,主要是由于较低的水动力使鲕粒悬浮生长受阻,导致包壳不对称生长(图3l)。
图 3 原生沉积鲕粒典型镜下照片
Figure 3. Typical photomicrographs of primary sedimentary ooids
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泥晶鲕圈层结构不发育,粒径较小,0.1~0.5 mm。在浪基面以下发生泥晶化,整体颜色较深,保存完整(图4a)。部分泥晶鲕颗粒间发育两期胶结,海水成因的纤状环边胶结以及等粒状大气淡水胶结(图4b),部分中心部位发生重结晶作用。变形鲕为鲕粒受压力发生塑性变形形成,因此在镜下观察时可见整个薄片的鲕粒都发生不同程度的变形(图4c)。鲕粒受溶蚀形成负鲕,研究区内负鲕粒径较小,可见附着于内壁或充填孔隙的沥青(图4d,e)。单晶鲕与多晶鲕多为负鲕接受大气淡水再沉淀而形成(图4f,g),可见示顶底结构(图4h),少数为重结晶作用形成。研究区白云石化作用较弱,见部分鲕粒外部同心层与基质被白云石化的白云化鲕(图4i),而残余鲕则被完全白云石化后只能大概识别其轮廓(图4j)。破碎鲕可根据其破碎特征划分为断壳鲕、破裂鲕、错断鲕以及残缺鲕(图4k)。后生成因偏心鲕为鲕粒内部圈层受到溶蚀,核心发生偏移后鲕粒内部孔隙再次沉淀结晶形成,可通过鲕粒圈层特征识别(图4l)。
图 4 后生改造鲕粒典型镜下照片
Figure 4. Typical photomicrographs of epigenetic ooids
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龙潭村剖面鲕粒主要发育于飞一段台缘鲕粒滩,飞二段仅见少量台内点滩,鲕粒总含量向上呈减少再增加趋势(图5)。泥晶鲕垂向分布较广,从底到顶其含量随同心鲕的减少逐渐增加,常伴随复鲕发育。同心鲕主要分布于飞一段下部,与破碎鲕的出现相吻合,而与表鲕的发育相反。负鲕同时或晚于同心鲕出现,根据其特征,可推断飞仙关早期龙潭村位于海平面附近,水动力较强且地层暴露遭受过大气淡水选择性溶蚀,同时单晶鲕的出现大多晚于负鲕,仅部分层段两者共存,单晶鲕发育的样品镜下可见大气淡水再沉淀形成的示顶底结构(图4h),且灰泥基质仅见微弱重结晶作用(图4f,g),因此单晶鲕的形成主要是受大气淡水中溶解碳酸钙再沉淀形成而不是因重结晶作用而形成。多晶鲕的分布和单晶鲕较为一致,但早于单晶鲕。椭形鲕分布较乱,在鲕粒滩与台内点滩中均发育。巨鲕发育于飞一段底部与其他类型鲕粒共生。剖面白云化作用弱,因此未见残余鲕,仅在14层见极少白云化鲕。
图 5 龙潭村剖面飞仙关组鲕粒特征及沉积综合柱状图
Figure 5. Ooid characteristics and comprehensive sedimentary column of Feixianguan Formation in Longtancun
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莱溪剖面鲕粒发育层位与龙潭村相似,但鲕粒类型与龙潭村有区别,且砂屑含量较高,鲕粒总含量向上逐渐减少(图6)。剖面未见同心鲕,泥晶鲕分布广泛,含量从飞一段底部向上逐渐减少。表鲕及复鲕仅发育于飞一段底部。飞一段底部及飞二段台缘鲕粒滩均见到鲕粒,但飞二段巨鲕含量比飞一段低。剖面单晶鲕及多晶鲕发育,未见负鲕,但是根据剖面单晶鲕中示顶底结构可以判断单晶鲕成因与龙潭村一致,多晶鲕发布较广,常与单晶鲕及负鲕伴生。白云化鲕与残余鲕在飞一段可见。破碎鲕主要发育在飞一段。藻鲕仅发育于39层。
图 6 莱溪剖面飞仙关组鲕粒特征及沉积综合柱状图
Figure 6. Ooid characteristics and comprehensive sedimentary column of Feixianguan Formation in Laixi
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鱼洞子剖面鲕粒主要发育于飞二段(图7)。泥晶鲕分布广,但从底部向上其含量随同心鲕含量的变化先减少再增加。显现出与同心鲕发育相反的趋势。剖面表鲕,复鲕及藻鲕发育较少,主要集中于22~28层。巨鲕在剖面内发育较多,且巨鲕大多以同心层形式出现,仅少量呈复鲕形式出现。剖面负鲕、单晶鲕及多晶鲕较为发育,且相关性较好。负鲕在飞二段顶部及其发育,形成大量铸模孔。单晶鲕与多晶鲕的发育与前两个基本剖面一致,常伴生出现。破碎鲕与变形鲕发育段吻合,集中于飞二段下部,该层段鲕粒形成后遭受成岩压实压溶作用,镜下可见缝合线穿过鲕粒。
图 7 鱼洞子剖面飞仙关组鲕粒特征及沉积综合柱状图
Figure 7. Ooid characteristics and comprehensive sedimentary column of Feixianguan Formation in Yudongzi
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鲕粒粒度与沉积环境水动力条件具有很强的相关性[17-31],且已有相关工作者将粒度分析方法用于颗粒碳酸盐岩及鲕粒碳酸盐岩研究[65-67]。台内滩鲕粒发育较少且分布不连续,因此以连续的台缘鲕粒滩对鲕粒粒度的时空演化进行研究。由于实测粒径转换为Φ值,因此平均粒径曲线变化趋势与鲕粒平均粒径大小变化相反,且前人通过分析确定的标准偏差划分碎屑岩分选性的标准,对碳酸盐岩分选性划分是不准确的,因此通过镜下鉴定来校正划分标准,鉴定结果与郭芪恒等[65]制定的下苇甸张夏组鲕粒分选划分标准基本一致,因此本文采用其划分标准(表1)。
分选级别 极好 好 较好 中等 较差 差 标准偏差(σ) <0.3 0.3~0.35 0.35~0.4 0.4~0.45 0.45~0.5 >0.5 偏度同样被用于判断沉积物分选性,但具有两种完全不同的含义。当明显不同的两个或多个粒度总体混合时,如果两个或多个含量相等,虽然偏度趋于0,却表现为差的分选,频率曲线形态呈马鞍状双峰或多峰对称型[53]。在碎屑岩研究中偏度与标准偏差对应性较好,但是由于鲕粒的成因及粒度关系复杂,粒径较大的鲕粒也能在弱水动力条件下形成。因此在碳酸盐岩的研究中,偏度对分选性的划分作用较小,但通过与标准偏差的结合可用于推测频率曲线形态。频率曲线形态能反映沉积环境水动力变化(图8a),单峰表示水动力条件稳定,与反映沉积物搬运方式的概率累计曲线(图8b)具有很强的相关性,对样品统计分析发现单峰型主要对应直线型,多峰型主要对应三段型(图9)。
图 8 粒度分析图
Figure 8. Pixel diameters
图 9 曲线特征对应关系
Figure 9. Curve feature correspondence
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对龙潭村剖面鲕粒粒度参数进行绘图分析,通过相关性分析生成预测线,通过大数定律与中心极限定理拟合确定95%可信区及95%预测区。研究显示剖面平均粒径(Mz)曲线从底到顶逐渐增大,但由于转换为Φ值,因此鲕粒实际平均粒径为逐渐减小(图10a)。鲕粒标准偏差逐渐减小(图10b),分选性由差到好。龙潭村鲕粒沉积偏度主要为正偏态(图10c)。峰度显示从底到顶鲕粒峰度由小变大(图10d),与标准偏差变化相反(图10e),与粒度变化相同。频率曲线形态多为单峰型,少数呈双峰及多峰型(图5)。
图 10 龙潭村剖面粒度参数散点图
Figure 10. Scatter graphs of granularity parameters in Longtancun
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莱溪剖面鲕粒从低到顶平均粒径经历增大—减小—增大三次变化,粒径增大的层段出现巨鲕(图11a)。标准偏差与粒径变化相同,呈现增大—减小—增大变化(图11b)。偏度大部分为正态,相关性较差,与龙潭村一致,仅可用于判断频率曲线形态(图11c)。峰度与平均粒径变化一致(图11d),与标准偏差负相关(图11e)。频率曲线形态与概率累计曲线各形态均出现,但主要为单峰型对应直线型,双峰型对应二段型,多峰型对应三段型(图6)。
图 11 莱溪剖面粒度参数散点图
Figure 11. Scatter graphs of granularity parameters in Laixi
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鱼洞子剖面鲕粒从低到顶鲕粒平均粒径与标准偏差向上减小(图12a,b),分选性逐渐变好。偏度多为正态(图12c),峰度向上减小,由于巨鲕的影响与前两个剖面呈现出不同的变化规律(图12d),与标准偏差呈负相关(图12e)。频率曲线主要为单峰型与双峰型,多峰型仅少量出现。概率累积曲线主要为直线型与二段型,三段型较少出现。单峰型常与直线型伴生,二段型与双峰型伴生(图7)。
图 12 鱼洞子剖面粒度参数散点图
Figure 12. Scatter graphs of granularity parameters in Yudongzi
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根据龙潭村、莱溪及鱼洞子剖面鲕粒类型及粒度时空演化对比分析,鲕粒类型及粒度参数与沉积环境具有较好的相关性。粒径较大的同心鲕、较大的标准偏差、多峰型频率曲线及三段式概率累计曲线,通常指示鲕粒滩沉积环境中水动力较强的活动边缘带。但部分巨鲕由泥晶灰泥充填(图3j)且含巨鲕的样品粒度参数与无巨鲕的样品差距较大,相关性较差(图10~12),这也证实巨鲕的形成受微生物作用及海水碳酸盐饱和度异常增大等多种因素的复合影响,而不仅仅只是水动力变强的原因。因此在利用粒度参数分析有巨鲕发育的鲕粒滩沉积水动力条件时,需对鲕粒粒度参数进行相关性分析,去除相关性较差的样品数据。泥晶鲕等粒度较小的鲕粒通常分选性较好,多为单峰与直线型,常发育于鲕粒滩沉积环境中水动力弱、稳定的稳定鲕粒砂坪。龙潭村剖面从底到顶由同心鲕,负鲕、多晶鲕为主,转变为泥晶鲕、单晶鲕、复鲕为主的同时,鲕粒平均粒径也逐渐减小,分选性由差变好,频率累计曲线由多峰型为主变为单峰型为主,概率累计曲线则由三段型向直线型转变。鲕粒类型及粒度参数显示,鲕粒滩水动力逐渐减小,沉积环境由活动边缘带转变为稳定鲕粒砂坪沉积。莱溪剖面从底到顶粒径增大再减小、频率曲线呈多峰型—单峰型—多峰型及概率累计曲线由三段型—直线型—三段型指示莱溪剖面鲕粒滩水动力减小再增大,沉积环境呈活动边缘带—稳定鲕粒砂坪—活动边缘带旋回。鱼洞子剖面巨鲕发育较多,整体上从底到顶由粒径较大的同心鲕转变为粒径较小的泥晶鲕,水动力逐渐减小,沉积环境由活动边缘带转变为稳定鲕粒砂坪沉积。但局部表现出异常的粒径及曲线形态,这是由于巨鲕的发育所导致的。
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(1) 川东北飞仙关组发育鲕粒有原生沉积的藻鲕、同心鲕、表鲕、复鲕、椭形鲕、巨鲕、偏心鲕及后生改造的泥晶鲕、偏心鲕、变形鲕、负鲕、单晶鲕、多晶鲕、白云化鲕、残余鲕、破碎鲕。
(2) 龙潭村飞仙关组台缘鲕粒滩由活动边缘带转变为稳定鲕粒砂坪沉积,水动力减弱;莱溪呈活动边缘带—稳定鲕粒砂坪—活动边缘带沉积旋回,水动力降低再增加;鱼洞子飞二段台缘鲕粒滩沉积,向上水动力逐渐变弱。
(3) 鲕粒类型及粒度参数时空演化与水动力具有良好的对应关系,但在巨鲕发育的层段这种对应关系可能会变差,这是由于巨鲕的形成可能主要是受微生物作用和碳酸盐饱和度的快速增加影响,而不是水动力的快速变化。因此在有巨鲕发育的层段利用鲕粒粒度分析沉积环境水动力时,不能简单地认为鲕粒粒径大则代表水动力更强。
Correlation Between Ooid Characteristics and Hydrodynamic Forces in the Feixianguan Formation, Northeastern Sichuan
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摘要:
早三叠世鲕粒在全球范围内广泛发育,且出现巨鲕。川东北飞仙关组台缘鲕粒滩非均质性强,鲕粒类型复杂。选择川东北龙潭村、莱溪及鱼洞子剖面进行野外实测、镜下鉴定及粒度分析,对鲕粒类型及粒度参数演化与水动力相关性进行研究。研究发现川东北飞仙关组发育7种原生沉积鲕粒,9种后生改造成因鲕粒,其中后生改造成因的破碎鲕可进一步细分。除偏度外,平均粒径、标准偏差、峰度等粒度参数及粒度资料图解曲线形态具有很强的相关性,与鲕粒类型结合判断龙潭村鲕粒滩由活动边缘带转变为稳定鲕粒砂坪沉积,水动力逐渐减小;莱溪呈活动边缘带—稳定鲕粒砂坪—活动边缘带沉积旋回,水动力先减小再增大;鱼洞子向上水动力逐渐减小。但含巨鲕的层位与整体的鲕粒类型及粒度变化趋势相关性较差,这可能是由于巨鲕异常大的粒径形成主要受微生物作用和海水碳酸盐岩饱和度的快速增大复合影响,而非水动力快速变化。因此,在利用粒度参数判断具有巨鲕发育的沉积环境水动力条件时,不能简单地凭借粒度便做出结论,需对鲕粒粒度参数进行相关性分析,去除相关性较差的样品数据。 Abstract:Ooids developed all over the world in the Lower Triassic, and giant ooids appeared. The ooid shoal at the margin of the Feixianguan Formation platform in northeastern Sichuan comprises strongly heterogeneous and complex ooid types. The relationship between ooid type, grain size parameter evolution and hydrodynamic forces were studied for deposits in the Longtancun, Laixi and Yudongzi regions using field measurement, microscopic identification and grain-size analysis. Seven primary divisions and nine subdivisions of ooids were found, and fractured ooids may be classed separately. In addition to skewness, other parameters (e.g., average particle size, standard deviation, kurtosis and graphic curve shape of particle size data) are strongly correlated. The classifications suggest that the ooid shoal at Longtan village indicates a change from an active marginal zone to a stable ooid sand flat as hydrodynamic conditions gradually decreased. At Laixi, a deposition cycle of active marginal zone-stable ooid sand flat to active marginal zone is evident, with decreasing and then increasing hydrodynamic force. The hydrodynamic force decreases with upward at Yudongzi. However, there is poor correlation between the horizon containing giant and the overall trend of changes in ooid grain type and size, possibly because the abnormally large particle size in the giant ooids is affected by a combination of microbial action and the rapid increase of seawater carbonate saturation rather than rapid change in hydrodynamic force. Therefore, when judging the hydrodynamic conditions of sedimentary environments containing giant ooids using grain-size parameters, it is not possible to draw a conclusion from grain size alone, but it is necessary to analyze the correlations between ooid grain-size parameters. -
图 3 原生沉积鲕粒典型镜下照片
(a)圈层不规则起伏的藻鲕,单偏光,LTC⁃14;(b)受两期胶结的藻鲕,单偏光,YDZ2⁃23⁃2;(c)同心鲕,单偏光,YDZ2⁃29⁃2;(d)核心被选择性溶蚀再沉淀的同心鲕,单偏光,YDZ2⁃31⁃1;(e)同心鲕部分圈层发生重结晶作用,单偏光,YDZ2⁃29⁃1⁃1;(f)表鲕,单偏光,YDZ2⁃21⁃1;(g)复鲕发生重结晶作用,单偏光,YDZ2⁃27⁃1⁃1;(h)复鲕外部包壳最内层可变厚度,单偏光,YDZ2⁃29⁃1⁃1;(i)具不规则核心控制的椭形鲕,单偏光,YDZ2⁃29⁃2;(j)以较大粒径作为核心的巨鲕,单偏光,YDZ2⁃29⁃1⁃1;(k)灰泥充填的巨鲕,部分圈层及基质发生重结晶,单偏光,YDZ2⁃29⁃1⁃1;(l)偏心鲕,单偏光,YDZ2⁃30⁃1⁃1
Figure 3. Typical photomicrographs of primary sedimentary ooids
图 4 后生改造鲕粒典型镜下照片
(a)泥晶鲕,圈层结构不发育,单偏光,YDZ2⁃29⁃1;(b)受两期胶结的泥晶鲕,单偏光,YDZ2⁃8⁃1⁃1;(c)变形鲕,单偏光,YDZ2⁃21⁃1;(d)负鲕,沥青部分充填,单偏光,YDZ2⁃44⁃5;(e)鲕粒溶蚀形成铸模孔,单偏光,YDZ⁃11⁃2⁃10;(f)单晶鲕,单偏光,LX⁃35⁃T;(g)多晶鲕,单偏光,LX⁃35⁃T;(h)单晶鲕,具示顶底结构,单偏光,LTC⁃14;(i)白云化鲕,单偏光,YDZ⁃12⁃1;(j)残余鲕,仅能大概识别形态,单偏光,YDZ⁃12⁃1;(k)破碎鲕,见多种次级划分类型,单偏光,YDZ2⁃27⁃1⁃1;(l)溶蚀再充填形成的后生偏心鲕,单偏光,YDZ2⁃27⁃1⁃1
Figure 4. Typical photomicrographs of epigenetic ooids
图 5 龙潭村剖面飞仙关组鲕粒特征及沉积综合柱状图
Figure 5. Ooid characteristics and comprehensive sedimentary column of Feixianguan Formation in Longtancun
图 6 莱溪剖面飞仙关组鲕粒特征及沉积综合柱状图
Figure 6. Ooid characteristics and comprehensive sedimentary column of Feixianguan Formation in Laixi
图 7 鱼洞子剖面飞仙关组鲕粒特征及沉积综合柱状图
Figure 7. Ooid characteristics and comprehensive sedimentary column of Feixianguan Formation in Yudongzi
图 10 龙潭村剖面粒度参数散点图
(a)Φ值变化图;(b)标准偏差变化图;(c)标准偏差与偏度关系图;(d)峰度变化图;(e)标准偏差与峰度关系图
Figure 10. Scatter graphs of granularity parameters in Longtancun
图 11 莱溪剖面粒度参数散点图
(a)Φ值变化图;(b)标准偏差变化图;(c)标准偏差与偏度关系图;(d)峰度变化图;(e)标准偏差与峰度关系图
Figure 11. Scatter graphs of granularity parameters in Laixi
图 12 鱼洞子剖面粒度参数散点图
(a)Φ值变化图;(b)标准偏差变化图;(c)标准偏差与偏度关系图;(d)峰度变化图;(e)标准偏差与峰度关系图
Figure 12. Scatter graphs of granularity parameters in Yudongzi
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