Illuminating the heterogeneous Earth based on numerical simulations of seismic waves: from global tomography to subduction-zone imaging

基于地震波数值模拟揭示异质地球：从全球层析成像到俯冲带成像

• 批准号: RGPIN-2016-06220
• 负责人: Liu, Qinya
• 金额: $ 2.11万
• 依托单位: University of Toronto
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2020
• 资助国家: 加拿大
• 起止时间: 2020-01-01 至 2021-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=710222
• 关键词: Illuminating; heterogeneous; Earth; based; numerical

Understanding the internal processes and dynamic evolution of our planet Earth has been one of the fundamental scientific questions for earth scientists. The tectonic events in the past are responsible for shaping the topographic and geological features observed on the surface, while the internal geodynamic circulation is the main engine driving complex plate motions. These plate motions and associated tectonic stress are often manifested as earthquakes, many of which cause severe damage over large areas. On the other hand, seismic waves emitted from these earthquakes provide an essential tool for illuminating heterogeneous structures of the Earth's interior and present direct evidence for the underlying tectonic processes. This proposal aims to continue our involvement in the development of forward seismic wave simulation techniques, and further advance innovative seismic imaging tools based on these numerical simulations to map internal structures of the Earth at both global and continental scales. For the whole globe, we will utilize a finite-frequency sensitivity kernel database computed fully numerically to generated updated shear and bulk-sound velocity models for the whole mantle. The large number of diffracted wave measurements will boost the resolution of the models above the core-mantle-boundary (CMB) and help provide better constraints on the Large Low Shear Velocity Provinces (LLSVPs) and ancient subducted slabs accumulating at the CMB. At regional scales, we will apply 2D and 3D SEM-FK hybrid techniques to both forward modelling and inversion of subduction zones beneath southern and central Alaska, with the goal of improving the locations and velocity variations of subducted oceanic crust and lithospheric mantle, the Moho interface and the overriding plate, and contributing to the interdisciplinary discussions on subduction zone processes.

了解地球的内部过程和动态演变一直是地球科学家的基本科学问题之一。过去的构造事件负责塑造在表面上观察到的地形和地质特征，而内部地球动力循环是主要的发动机驱动复杂板运动。这些板块运动和相关的构造应力通常表现为地震，其中许多在大面积上造成严重破坏。另一方面，从这些地震发出的地震波为阐明地球内部的异质结构提供了必不可少的工具，并为基础构造过程提供了直接证据。该建议旨在继续我们参与前向地震波模拟技术的发展，并基于这些数值模拟进一步推进创新的地震成像工具，以在全球和大陆尺度上绘制地球的内部结构。 对于整个地球，我们将利用一个有限频率灵敏度内核数据库，该数据库完全数值​​计算为整个地幔生成的更新的剪切和散装速度模型。大量的衍射波测量值将提高模型的分辨率（CMB），并有助于对大型低剪切速度省（LLSVPS）和古老的支号板的限制提供更好的约束，并在CMB处积累。在区域尺度上，我们将在阿拉斯加南部和中部的俯冲区域进行2D和3D SEM-FK混合技术，以改善俯冲俯冲的海洋壳和岩石层壁炉的位置和速度变化，Mohoho，Mohoho的速度变化的目的界面和覆盖板，并为俯冲带过程的跨学科讨论做出了贡献。