Major methods of seismic anisotropy

Earthquake Research Advances Pub Date : 2024-07-01 DOI:10.1016/j.eqrea.2024.100295

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Abstract

Seismic anisotropy reveals that seismic wave velocity, amplitude, and other physical properties show variations in different directions, which can be divided into lattice-preferred orientation (LPO) and shape-preferred orientation (SPO) according to its physical mechanisms. The main methods for studying seismic anisotropy include shear-wave splitting analysis, P-wave travel time inversion and surface-wave tomography, etc. There are some differences and correlations among these methods. Seismic anisotropy is an important way to reveal the dynamic processes of crust-mantle evolution, and it is significant for monitoring crustal stress changes and improve seismic exploration studies. With the help of long-term observation, the application of machine learning techniques and combining inversion based on multiple phases would become potential developments in seismic anisotropy studies. This may improve the understanding of complex seismic anisotropic models, such as multiple layers anisotropy with an oblique axis of symmetry.

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地震各向异性的主要研究方法

地震各向异性揭示了地震波速度、振幅和其他物理性质在不同方向上的变化，按其物理机制可分为晶格偏好方位（LPO）和形状偏好方位（SPO）。研究地震各向异性的主要方法有剪切波分裂分析法、P 波旅行时间反演法和面波层析成像法等。这些方法之间存在一些差异和关联。地震各向异性是揭示地壳-地幔动态演化过程的重要途径，对监测地壳应力变化和改进地震勘探研究具有重要意义。在长期观测的帮助下，机器学习技术的应用和基于多相的组合反演将成为地震各向异性研究的潜在发展方向。这可能会提高对复杂地震各向异性模型的理解，如具有斜对称轴的多层各向异性。

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Earthquake Research Advances

CiteScore

4.30

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0.00%

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