{"title":"各向异性结构的三维体波图像捕捉到的大陆岩石圈拼凑结构","authors":"Jaroslava Plomerová","doi":"10.1016/j.jog.2024.102041","DOIUrl":null,"url":null,"abstract":"<div><p>This paper presents an overview of research conducted for more than five decades around Vladislav Babuška and collaborators on large-scale seismic anisotropy in tectonically different regions of continental lithosphere in Europe. A wide range of independent data sets and methods are covered. It also briefly touches laboratory measurements of velocity anisotropy on rock samples from the crust and the upper mantle, and emphasizes the importance of considering anisotropy in studies of the Earth structure. The anisotropy is responsible for even larger velocity variations than those due to composition of the most abundant upper mantle rocks (peridotites). The large-scale in-situ measurements of the upper mantle anisotropy capture fabrics of the mantle lithosphere, and enables mapping lateral changes in its structure. The joint inversion/interpretation of the teleseismic body-wave anisotropic parameters, such as variations of directional terms of relative travel time residuals of P waves, shear-wave splitting or the coupled anisotropic-isotropic teleseismic P-wave tomography, image the continental lithosphere as a mosaic of anisotropic domains. Each of the domains has its own thickness and fossil fabric characterized by tilted symmetry axes. We map boundaries of the domains in dependence on the fabric changes. The boundaries can be either narrow and steep or broader and inclined, with an offset relative to boundaries of the related crustal bocks, which can reach several tens of kilometres. This overview presents the European lithosphere-asthenosphere boundary (LAB) and shows examples of anisotropic fabrics of the mantle lithosphere domains and their boundaries in different parts of the European plate.</p></div>","PeriodicalId":54823,"journal":{"name":"Journal of Geodynamics","volume":"161 ","pages":"Article 102041"},"PeriodicalIF":2.1000,"publicationDate":"2024-07-22","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://www.sciencedirect.com/science/article/pii/S0264370724000243/pdfft?md5=ed1b60fa3cbd085f1369a8c8a17eb9a0&pid=1-s2.0-S0264370724000243-main.pdf","citationCount":"0","resultStr":"{\"title\":\"Patchwork structure of continental lithosphere captured in 3D body wave images of its anisotropic fabrics\",\"authors\":\"Jaroslava Plomerová\",\"doi\":\"10.1016/j.jog.2024.102041\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<div><p>This paper presents an overview of research conducted for more than five decades around Vladislav Babuška and collaborators on large-scale seismic anisotropy in tectonically different regions of continental lithosphere in Europe. A wide range of independent data sets and methods are covered. It also briefly touches laboratory measurements of velocity anisotropy on rock samples from the crust and the upper mantle, and emphasizes the importance of considering anisotropy in studies of the Earth structure. The anisotropy is responsible for even larger velocity variations than those due to composition of the most abundant upper mantle rocks (peridotites). The large-scale in-situ measurements of the upper mantle anisotropy capture fabrics of the mantle lithosphere, and enables mapping lateral changes in its structure. The joint inversion/interpretation of the teleseismic body-wave anisotropic parameters, such as variations of directional terms of relative travel time residuals of P waves, shear-wave splitting or the coupled anisotropic-isotropic teleseismic P-wave tomography, image the continental lithosphere as a mosaic of anisotropic domains. Each of the domains has its own thickness and fossil fabric characterized by tilted symmetry axes. We map boundaries of the domains in dependence on the fabric changes. The boundaries can be either narrow and steep or broader and inclined, with an offset relative to boundaries of the related crustal bocks, which can reach several tens of kilometres. 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引用次数: 0
摘要
本文概述了弗拉迪斯拉夫-巴布š卡及其合作者五十多年来对欧洲大陆岩石圈构造不同区域的大尺度地震各向异性进行的研究。报告涵盖了各种独立的数据集和方法。报告还简要介绍了对地壳和上地幔岩石样本进行的速度各向异性实验室测量,并强调了在地球结构研究中考虑各向异性的重要性。各向异性造成的速度变化甚至比最丰富的上地幔岩石(橄榄岩)成分造成的速度变化还要大。对上地幔各向异性的大规模原位测量可以捕捉地幔岩石圈的结构,并绘制其结构的横向变化图。远震体波各向异性参数的联合反演/解释,如 P 波相对旅行时间残差的方向项变化、剪切波分裂或各向异性-各向同性耦合远震 P 波层析成像,将大陆岩石圈成像为各向异性域的镶嵌图。每个畴都有自己的厚度和以倾斜对称轴为特征的化石结构。我们根据构造的变化绘制畴的边界。边界可以是狭窄陡峭的,也可以是宽阔倾斜的,相对于相关地壳块体的边界会有偏移,偏移距离可达几十公里。本概述介绍了欧洲岩石圈-岩石圈边界(LAB),并举例说明了欧洲板块不同地区地幔岩石圈域及其边界的各向异性结构。
Patchwork structure of continental lithosphere captured in 3D body wave images of its anisotropic fabrics
This paper presents an overview of research conducted for more than five decades around Vladislav Babuška and collaborators on large-scale seismic anisotropy in tectonically different regions of continental lithosphere in Europe. A wide range of independent data sets and methods are covered. It also briefly touches laboratory measurements of velocity anisotropy on rock samples from the crust and the upper mantle, and emphasizes the importance of considering anisotropy in studies of the Earth structure. The anisotropy is responsible for even larger velocity variations than those due to composition of the most abundant upper mantle rocks (peridotites). The large-scale in-situ measurements of the upper mantle anisotropy capture fabrics of the mantle lithosphere, and enables mapping lateral changes in its structure. The joint inversion/interpretation of the teleseismic body-wave anisotropic parameters, such as variations of directional terms of relative travel time residuals of P waves, shear-wave splitting or the coupled anisotropic-isotropic teleseismic P-wave tomography, image the continental lithosphere as a mosaic of anisotropic domains. Each of the domains has its own thickness and fossil fabric characterized by tilted symmetry axes. We map boundaries of the domains in dependence on the fabric changes. The boundaries can be either narrow and steep or broader and inclined, with an offset relative to boundaries of the related crustal bocks, which can reach several tens of kilometres. This overview presents the European lithosphere-asthenosphere boundary (LAB) and shows examples of anisotropic fabrics of the mantle lithosphere domains and their boundaries in different parts of the European plate.
期刊介绍:
The Journal of Geodynamics is an international and interdisciplinary forum for the publication of results and discussions of solid earth research in geodetic, geophysical, geological and geochemical geodynamics, with special emphasis on the large scale processes involved.