Various Approaches to Forward and Inverse Wide-Angle Seismic Modelling Tested on Data from DOBRE-4 Experiment

IF 2 4区 地球科学 Q2 GEOCHEMISTRY & GEOPHYSICS Acta Geophysica Pub Date : 2016-12-28 DOI:10.1515/acgeo-2016-0084
T. Janik, P. Środa, W. Czuba, D. Lysynchuk
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引用次数: 3

Abstract

The interpretation of seismic refraction and wide angle reflection data usually involves the creation of a velocity model based on an inverse or forward modelling of the travel times of crustal and mantle phases using the ray theory approach. The modelling codes differ in terms of model parameterization, data used for modelling, regularization of the result, etc. It is helpful to know the capabilities, advantages and limitations of the code used compared to others.This work compares some popular 2D seismic modelling codes using the dataset collected along the seismic wide-angle profile DOBRE-4, where quite peculiar/uncommon reflected phases were observed in the wavefield.The ~505 km long profile was realized in southern Ukraine in 2009, using 13 shot points and 230 recording stations. Double PMP phases with a different reduced time (7.5–11 s) and a different apparent velocity, intersecting each other, are observed in the seismic wavefield. This is the most striking feature of the data. They are interpreted as reflections from strongly dipping Moho segments with an opposite dip. Two steps were used for the modelling. In the previous work by Starostenko et al. (2013), the trial-and-error forward model based on refracted and reflected phases (SEIS83 code) was published. The interesting feature is the high-amplitude (8–17 km) variability of the Moho depth in the form of downward and upward bends. This model is compared with results from other seismic inversion methods: the first arrivals tomography package FAST based on first arrivals; the JIVE3D code, which can also use later refracted arrivals and reflections; and the forward and inversion code RAYINVR using both refracted and reflected phases. Modelling with all the codes tested showed substantial variability of the Moho depth along the DOBRE-4 profile. However, SEIS83 and RAYINVR packages seem to give the most coincident results.
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基于DOBRE-4试验数据的多种广角地震正反演模拟方法
地震折射和广角反射数据的解释通常涉及到利用射线理论方法对地壳和地幔相的移动时间进行逆或正演模拟,从而建立一个速度模型。建模代码在模型参数化、用于建模的数据、结果的正则化等方面有所不同。与其他代码相比,了解所使用代码的功能、优点和限制是有帮助的。这项工作使用沿地震广角剖面DOBRE-4收集的数据集比较了一些流行的二维地震建模代码,在波场中观察到相当特殊/不常见的反射相位。2009年在乌克兰南部实现了~505公里长的剖面,使用了13个拍摄点和230个记录站。在地震波场中观测到具有不同缩减时间(7.5 ~ 11 s)和不同视速度的双PMP相相交。这是数据中最显著的特征。它们被解释为强烈倾斜的莫霍段与相反倾斜的反射。建模分为两个步骤。在starostonko等人(2013)之前的工作中,发表了基于折射和反射相位的试错正演模型(SEIS83代码)。有趣的特征是莫霍深度的高振幅(8-17 km)变化,以向下和向上弯曲的形式出现。该模型与其他地震反演方法的结果进行了比较:基于首到层析成像的FAST包;JIVE3D代码,也可以使用后期折射到达和反射;以及同时使用折射相位和反射相位的正反演代码RAYINVR。所有测试代码的建模显示,沿DOBRE-4剖面的莫霍深度存在实质性变化。然而,SEIS83和RAYINVR包似乎给出了最一致的结果。
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来源期刊
Acta Geophysica
Acta Geophysica 地学-地球化学与地球物理
CiteScore
3.90
自引率
13.00%
发文量
251
审稿时长
5.3 months
期刊介绍: Acta Geophysica is open to all kinds of manuscripts including research and review articles, short communications, comments to published papers, letters to the Editor as well as book reviews. Some of the issues are fully devoted to particular topics; we do encourage proposals for such topical issues. We accept submissions from scientists world-wide, offering high scientific and editorial standard and comprehensive treatment of the discussed topics.
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