Casper山断裂带和怀俄明州周边地区的结构分析:对整个怀俄明州的Laramide运动学和结构继承的影响

J. Bader
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引用次数: 1

摘要

卡斯珀山是一个东西向背斜构造,北受斜滑卡斯珀山断裂束缚。该断裂被认为反映了在拉腊酰胺造山运动期间被重新激活和/或引导变形的前寒武纪构造/构造。对断裂带及其周围地区的构造分析证实了这一假设,并对前寒武纪起源和Laramide运动学进行了深入了解。用于结构分析的地表和地下数据是从众多已发表的资料中收集和综合的,这些资料沿着拟议的变形走廊,大致与怀俄明州中部的俄勒冈小径结构带一致。卡斯珀山断裂带的特征是一条东西向直向的宽宽陡斜断裂带。卡斯珀山断层走向东西向,区内较小的断层走向N65°E。褶皱走向WNW,为左步。卡斯珀山前寒武纪岩石的叶理取向与卡斯珀山断裂近平行。北花岗山脉断裂带位于卡斯珀山正西,同样是东西向,其伴生断裂远离主控断裂,向NE、NW/SE和ENE/WSW方向发展。曲线形、左步状、纵向褶皱向西北延伸,在南侧被北花岗山脉断裂截断。风河山脉中部波波阿吉尔原始区基底岩断裂以东西向、北北西向、北东向等中、高角度断裂为特征,与图上的地表轮廓和构造资料相吻合。构造资料表明,Casper Mountain断裂的Laramide变形受前寒武纪各向异性的引导。断裂带和西部变形走廊的地表和地下填图表明,卡斯珀山和北花岗山脉断裂是基底-根断裂(扳手断裂)的一部分,可能向西延伸至波波阿吉尔原始区。在这里,陡倾(75-90°)的主断层暴露在西北西向的断层走廊中,该断层走廊与陡倾、北东向的元古代辉绿岩岩脉呈弧形偏移。这些岩脉很可能侵入了与西北西向断层相对的老断层。其他断层走向NNW,倾角较浅,为45-65°。这三个各向异性方向(WNW、NE和NNW)被认为是由沿一个长期存在的新太古代活跃大陆边缘的西南向北俯冲形成的。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Structural analysis of the Casper Mountain fault zone and area, Wyoming surrounding area, Wyoming: Implications for Laramide kinematics and structural inheritance across the Wyoming Province
Casper Mountain is an E–W trending anticlinal structure that is bound on the north by the oblique-slip Casper Mountain fault. The fault is postulated to reflect preexisting Precambrian structure/fabrics that were reactivated and/or guided deformation during the Laramide orogeny. A structural analysis of the fault zone and surrounding area was conducted to confirm this hypothesis, and to garner insight into both Precambrian origins and Laramide kinematics. Surface and subsurface data for structural analysis was collected and synthesized from numerous published sources along the proposed deformation corridor that roughly coincides with the Oregon Trail structural belt of central Wyoming. The Casper Mountain fault zone is characterized by an E–W rectilinear zone of en échelon, steeply inclined faults. The Casper Mountain fault strikes E–W with smaller faults in the zone striking N65°E. Folds trend to the WNW and are left-stepping. Foliations in Precambrian rocks of Casper Mountain are oriented subparallel to the Casper Mountain fault. The North Granite Mountains fault zone is located due west of Casper Mountain and is similarly oriented E–W with associated faults striking NE, NW/SE, and ENE/WSW, off the dominant master fault. Curvilinear, left-stepping, en échelon folds trend to the northwest and are truncated on the south by the North Granite Mountains fault. Faults in basement rocks of the Popo Agie Primitive Area of the central Wind River Mountains are characterized by moderate to high-angle faults striking E–W, NNW, and NE that coincide with mapped surface lineaments and fabric data. Fabric data suggest that Laramide deformation along the Casper Mountain fault was guided by Precambrian anisotropies. Surface and subsurface mapping of the fault zone and the deformation corridor to the west indicate that the Casper Mountain and North Granite Mountains faults are part of a basement-rooted system (wrench fault) that likely extends westward into the Popo Agie Primitive Area. Here, the steeply inclined (75–90°) proposed master fault is exposed within a WNW-striking corridor of faults that sinistrally offset steeply dipping, NE-striking Proterozoic diabase dikes. The dikes likely intruded older faults that are antithetic to the WNW-striking faults. Other faults strike to the NNW and have shallower dips of 45–65°. These three directions of anisotropy (WNW, NE, and NNW) are proposed to have formed from SW–NE-directed subduction along a long-lived, Neoarchean, active continental margin.
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