来自德国里斯撞击构造的冲击石英的平面变形特征的非发光性质:一种新的解释

Central European Geology Pub Date : 2015-11-28 DOI:10.1556/24.58.2015.3.2

A. Gucsik, T. Okumura, H. Nishido, I. Gyollai, K. Ninagawa, N. Deseta, P. Rózsa

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引用次数: 1

摘要

利用扫描电子显微镜(SEM-CL)、二次电子(SEM-SE)和背散射电子(SEM-BSE)模式以及Mott-Seitz分析对Ries冲击结构中含有冲击诱导微结构的石英颗粒进行了研究。本研究的目的是评价石英中平面变形特征(Planar Deformation Features, PDFs)的探测机制，PDFs是造岩矿物中冲击变质作用的重要指标之一。pdf是微米级的特征，不容易识别使用光学显微镜或扫描电子显微镜。在较高的冲击压力下，石英中pdf的CL谱在385 nm附近没有或有较弱的发射带，而在650 nm附近有一个不受冲击压力影响的最大发射带。因此，随着冲击变质阶段的增加，~385 nm波段的强度呈下降趋势，而650 nm波段则保持相当稳定。re……

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Non-luminescent nature of the planar deformation features in shocked quartz from the Ries impact structure, Germany: A new interpretation

Quartz grains from the Ries impact structure containing shock-induced microstructures were investigated using Scanning Electron Microscopy in cathodoluminescence (SEM-CL), secondary electron (SEM-SE) and back-scattered electron (SEM-BSE) modes as well as Mott–Seitz analysis. The purpose of this study is to evaluate the mechanism by which CL detects Planar Deformation Features (PDFs) in quartz, which is one of the most important indicators of shock metamorphism in rock-forming minerals. PDFs are micron-scale features not easily identified using optical microscopy or scanning electron microscopy. The CL spectrum of PDFs in quartz that has suffered relatively high shock pressure shows no or a relatively weak emission band at around 385 nm, whereas an emission band with a maximum near 650 nm is observed independent of shock pressure. Thus, the ~385 nm intensity in shocked quartz demonstrates a tendency to decrease with increasing shock metamorphic stage, whereas the 650 nm band remains fairly constant. The re...

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来源期刊

Central European Geology Earth and Planetary Sciences-Geology

CiteScore

1.40

自引率

0.00%

发文量