Mar Simonet Roda, Daeyeong Kim, Alexander T. Brasier, E. Griesshaber, Jeong‐Hyun Lee
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Both microsparitic layers are micrometre‐thick and are characterized by poorly co‐oriented calcite grains, but differ in their composition. Type 1 is depleted in magnesium but enriched in detrital elements such as silicon and aluminium, likely originating from the trapping and binding of detrital sediments on microbial mats during rainy seasons. In contrast, type 2 is enriched in magnesium but devoid of detrital elements, interpreted to have formed by the precipitation of calcium carbonate during dry seasons. The crystalline layers comprise fan‐shaped calcite crystals (ca 500 μm in length) with radiating internal structures, with their c‐axes oriented perpendicular to the stromatolite layers. These structures resemble those observed in some modern freshwater stromatolites, which are interpreted as imprints of cyanobacterial fascicules. While the cyclic occurrence of types 1 and 2 microsparitic layers might imply annual seasonal cycles, the less frequent crystalline layers are interpreted as a result of environmental changes occurring every 27 to 30 years. This is the first study to apply Electron Backscatter Diffraction to stromatolites, showcasing its potential in unravelling both the formative and diagenetic processes of ancient stromatolites.","PeriodicalId":2,"journal":{"name":"ACS Applied Bio Materials","volume":null,"pages":null},"PeriodicalIF":4.6000,"publicationDate":"2024-07-16","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Exploring electron backscatter diffraction analysis as a tool for understanding stromatolite: Quantitative description of Cretaceous lacustrine stromatolite reveals formative processes and high‐resolution climatic cycles\",\"authors\":\"Mar Simonet Roda, Daeyeong Kim, Alexander T. 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引用次数: 0
摘要
湖相叠层石是记录环境变化的重要档案,对其微观结构的详细研究对于了解其形成过程和其中蕴含的环境变化至关重要。本研究探索了电子反向散射衍射与能量色散 X 射线光谱相结合的应用,以研究韩国东南部的一个保存完好的中白垩世湖相叠层石,揭示了超高分辨率的沉积过程,而这些过程往往是传统方法难以观察到的。根据纹理、晶体形态和元素组成,区分了两种微石英层和一种结晶层。这两种微石英层都有微米厚,其特点是方解石晶粒共向性差,但成分不同。类型 1 的镁含量较低,但硅和铝等碎屑元素含量较高,这可能是由于雨季时微生物垫上的碎屑沉积物被捕获和结合造成的。与此相反,2 型富含镁,但不含碎屑元素,可以解释为是由碳酸钙在干旱季节沉淀形成的。结晶层由扇形方解石晶体(长约 500 μm)组成,内部结构呈放射状,其 c 轴方向与叠层石层垂直。这些结构类似于在一些现代淡水叠层石中观察到的结构,被解释为蓝藻簇的印记。第一类和第二类微石英层的周期性出现可能意味着每年的季节性周期,而较少出现的结晶层则被解释为每 27 至 30 年发生一次环境变化的结果。这是首次将电子反向散射衍射应用于叠层石的研究,展示了电子反向散射衍射在揭示古叠层石的形成和成岩过程方面的潜力。
Exploring electron backscatter diffraction analysis as a tool for understanding stromatolite: Quantitative description of Cretaceous lacustrine stromatolite reveals formative processes and high‐resolution climatic cycles
Lacustrine stromatolites serve as important archives for recording environmental changes, and the detailed examination of their microfabrics is essential for understanding their formative processes and the environmental changes embedded within them. This study explored the application of Electron Backscatter Diffraction combined with Energy‐Dispersive X‐ray Spectroscopy to investigate a well‐preserved middle Cretaceous lacustrine stromatolite from south‐eastern Korea, unveiling ultra‐high‐resolution sedimentary processes that are often challenging to observe using conventional methods. Two types of microsparitic layers and one type of crystalline layer are distinguished based on their texture, crystal morphology and elemental composition. Both microsparitic layers are micrometre‐thick and are characterized by poorly co‐oriented calcite grains, but differ in their composition. Type 1 is depleted in magnesium but enriched in detrital elements such as silicon and aluminium, likely originating from the trapping and binding of detrital sediments on microbial mats during rainy seasons. In contrast, type 2 is enriched in magnesium but devoid of detrital elements, interpreted to have formed by the precipitation of calcium carbonate during dry seasons. The crystalline layers comprise fan‐shaped calcite crystals (ca 500 μm in length) with radiating internal structures, with their c‐axes oriented perpendicular to the stromatolite layers. These structures resemble those observed in some modern freshwater stromatolites, which are interpreted as imprints of cyanobacterial fascicules. While the cyclic occurrence of types 1 and 2 microsparitic layers might imply annual seasonal cycles, the less frequent crystalline layers are interpreted as a result of environmental changes occurring every 27 to 30 years. This is the first study to apply Electron Backscatter Diffraction to stromatolites, showcasing its potential in unravelling both the formative and diagenetic processes of ancient stromatolites.