R. Gottardi, Gabriele Casale, J. Economou, Kristen Morris
{"title":"A little mica goes a long way: Impact of phyllosilicates on quartz deformation fabrics in naturally deformed rocks","authors":"R. Gottardi, Gabriele Casale, J. Economou, Kristen Morris","doi":"10.1130/g52053.1","DOIUrl":null,"url":null,"abstract":"Quartz deformation fabrics reflect stress and strain conditions in mylonites, and their interpretation has become a mainstay of kinematic and structural analysis. Quantification of grain size and shape and interpretation of textures reflecting deformation mechanisms can provide estimates of flow stress, strain rate, kinematic vorticity, and deformation temperatures. Empirical calibration and determination of quartz flow laws is based on laboratory experiments of pure samples; however, pure quartzite mylonites are relatively uncommon. In particular, phyllosilicates may localize and partition strain that can inhibit or enhance different deformation mechanisms. Experimental results demonstrate that even minor phyllosilicate content (<15 vol%) can dramatically alter the strain behavior of quartz; however, few field studies have demonstrated these effects in a natural setting.\n To investigate the role of phyllosilicates on quartz strain fabrics, we quantify phyllosilicate content and distribution in quartzite mylonites from the Miocene Raft River detachment shear zone (NW Utah, USA). We use microstructural analysis and electron backscatter diffraction to quantify quartz deformation fabrics and muscovite spatial distribution, and X-ray computed tomography to quantify muscovite content in samples with varying amounts of muscovite collected across the detachment shear zone. Phyllosilicate content has a direct control on quartz deformation mechanisms, and application of piezometers and flow laws based on quartz deformation fabrics yield strain rates and flow stresses that vary by up to two orders of magnitude across our samples. These findings have important implications for the application of flow laws in quartzite mylonites and strain localization mechanisms in mid-crustal shear zones.","PeriodicalId":503125,"journal":{"name":"Geology","volume":null,"pages":null},"PeriodicalIF":0.0000,"publicationDate":"2024-04-16","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Geology","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.1130/g52053.1","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 0
Abstract
Quartz deformation fabrics reflect stress and strain conditions in mylonites, and their interpretation has become a mainstay of kinematic and structural analysis. Quantification of grain size and shape and interpretation of textures reflecting deformation mechanisms can provide estimates of flow stress, strain rate, kinematic vorticity, and deformation temperatures. Empirical calibration and determination of quartz flow laws is based on laboratory experiments of pure samples; however, pure quartzite mylonites are relatively uncommon. In particular, phyllosilicates may localize and partition strain that can inhibit or enhance different deformation mechanisms. Experimental results demonstrate that even minor phyllosilicate content (<15 vol%) can dramatically alter the strain behavior of quartz; however, few field studies have demonstrated these effects in a natural setting.
To investigate the role of phyllosilicates on quartz strain fabrics, we quantify phyllosilicate content and distribution in quartzite mylonites from the Miocene Raft River detachment shear zone (NW Utah, USA). We use microstructural analysis and electron backscatter diffraction to quantify quartz deformation fabrics and muscovite spatial distribution, and X-ray computed tomography to quantify muscovite content in samples with varying amounts of muscovite collected across the detachment shear zone. Phyllosilicate content has a direct control on quartz deformation mechanisms, and application of piezometers and flow laws based on quartz deformation fabrics yield strain rates and flow stresses that vary by up to two orders of magnitude across our samples. These findings have important implications for the application of flow laws in quartzite mylonites and strain localization mechanisms in mid-crustal shear zones.
石英变形织构反映了麦饭石中的应力和应变条件,对它们的解释已成为运动学和结构分析的支柱。对晶粒尺寸和形状的量化以及对反映变形机制的纹理的解释,可以提供对流动应力、应变率、运动涡度和变形温度的估计。石英流动规律的经验校准和确定是基于纯样品的实验室实验;然而,纯石英岩麦饭石相对并不常见。特别是,辉绿硅酸盐可能会局部分配应变,从而抑制或增强不同的变形机制。实验结果表明,即使少量的植硅体含量(<15 vol%)也能显著改变石英的应变行为;然而,很少有野外研究能在自然环境中证明这些影响。为了研究植硅体对石英应变结构的作用,我们对中新世筏河分离剪切带(美国犹他州西北部)石英岩岩体中的植硅体含量和分布进行了量化。我们利用微结构分析和电子反向散射衍射来量化石英变形结构和蕈云母的空间分布,并利用 X 射线计算机断层扫描来量化在整个脱离剪切带采集的不同蕈云母含量的样品中的蕈云母含量。叶硅酸盐含量对石英的变形机制有直接的控制作用,根据石英变形结构应用压强计和流动定律得出的应变率和流动应力在我们的样本中相差达两个数量级。这些发现对石英岩麦饭石中流动规律的应用以及中壳剪切带的应变定位机制具有重要意义。