Geodynamic studies of southwestern Canada: Subduction zone processes and backarc mantle dynamics

IF 1.3 4区地球科学 Q3 GEOSCIENCES, MULTIDISCIPLINARY

Canadian Journal of Earth Sciences Pub Date : 2023-06-27 DOI:10.1139/cjes-2022-0140

C. Currie, Tai‐Chieh Yu

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Abstract

Geodynamic models allow insights into the processes that control lithosphere structure and evolution. Here, we highlight geodynamic studies along a profile through southwestern Canada, from the Cascadia subduction zone into the Laurentian craton. Geophysical and geological observations show distinct changes in thermal structure along this profile. One major change is between the cool forearc and hot volcanic arc. This marks the transition from (1) a stagnant forearc mantle that is cooled by the subducting Juan de Fuca Plate to (2) an advection-dominated arc region, where high temperatures arise from mantle flow driven by the subducting plate (corner flow). High temperatures occur for 400-500 km east of the arc to the Rocky Mountain Trench (RMT), where lithosphere thickness increases from 60-70 km below the Cordillera to >200 km below the craton. The timing of Cordillera lithosphere thinning is debated. A long-lived (>100 Ma) thin lithosphere inherited from earlier tectonics requires vigorous convection of a weak, hydrated mantle. Conversely, thinning may have occurred through gravitational removal of the lower lithosphere in the Eocene. Models show that a removal event only allows for a short-lived thin lithosphere (~25 Myr), owing to conductive cooling. Even if there was Eocene delamination, the present-day thin lithosphere requires small-scale convection in the Cordillera mantle. The thermal contrast across the RMT is enhanced by edge-driven convection at the Cordillera-craton lithosphere step. The step itself is an enigmatic feature, and its long-term preservation requires that the craton mantle lithosphere is strong (dry) with moderate chemical depletion.

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加拿大西南部地球动力学研究:俯冲带过程和弧后地幔动力学

地球动力学模型使我们能够深入了解控制岩石圈结构和演化的过程。在这里，我们重点介绍了从卡斯卡迪亚俯冲带到劳伦森克拉通的加拿大西南部剖面的地球动力学研究。地球物理和地质观测表明沿这条剖面热结构有明显的变化。一个主要的变化发生在凉爽的前弧和炎热的火山弧之间。这标志着从(1)由胡安·德·富卡板块俯冲冷却的停滞的弧前地幔到(2)由平流主导的弧区，由俯冲板块驱动的地幔流动(角流)产生高温。高温发生在弧东至落基山沟(RMT) 400-500公里处，岩石圈厚度从科迪勒拉以下60-70公里增加到克拉通以下200公里。科迪勒拉岩石圈减薄的时间存在争议。从早期构造继承而来的长寿命(>100 Ma)的薄岩石圈需要弱水合地幔的强烈对流。相反，变薄可能是由于始新世下部岩石圈的重力移走。模型显示，由于导电冷却，移动事件只允许短暂的薄岩石圈(~ 25myr)存在。即使始新世有剥离作用，现今的薄岩石圈也需要科迪勒拉地幔的小规模对流。在科迪勒拉-克拉通岩石圈阶段，边缘驱动的对流增强了RMT上的热对比。这个台阶本身就是一个谜，它的长期保存要求克拉通地幔岩石圈是强的(干燥的)和适度的化学消耗。

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来源期刊

Canadian Journal of Earth Sciences 地学-地球科学综合

CiteScore

2.80

自引率

7.10%

发文量

审稿时长

6-12 weeks

期刊介绍： The Canadian Journal of Earth Sciences reports current research in climate and environmental geoscience; geoarchaeology and forensic geoscience; geochronology and geochemistry; geophysics; GIS and geomatics; hydrology; mineralogy and petrology; mining and engineering geology; ore deposits and economic geology; paleontology, petroleum geology and basin analysis; physical geography and Quaternary geoscience; planetary geoscience; sedimentology and stratigraphy; soil sciences; and structural geology and tectonics. It also publishes special issues that focus on information and studies about a particular segment of earth sciences.