Mapping structures on the core-mantle boundary using Sdiff postcursors: Part I. Method and Validation

IF 2.8 3区 地球科学 Q2 GEOCHEMISTRY & GEOPHYSICS
Carl Martin, Thomas Bodin, S. Cottaar
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引用次数: 0

Abstract

Ultra-Low Velocity Zones (ULVZs) are patches of extremely slow seismic velocities on the core-mantle boundary. Here, we target them using the postcursors to S core-diffracted phases (Sdiff) caused by ULVZs. We use travel times of these postcursors to make probabilistic maps using a reversible-jump Markov chain Monte Carlo inversion setup. For the forward model, we extend 2D wavefront tracking (2DWT) software, previously developed for surface wave multipathing studies, to the core-mantle boundary. The 2DWT is able to model the full multipathing behaviour of Sdiff postcursors and compute arrival times for a given ULVZ input velocity structure on the order of a few CPU seconds, as opposed to 100s of CPU hours required for 3D full waveform synthetics. We validate the method using synthetic data sets produced by the 2DWT, as well as 3D full waveform synthetics, using a parameterisation formed from a collection of ellipses. We also test idealistic data coverage versus a case of more realistic coverage. We show ULVZ size and velocity reduction can typically be well recovered, and our maps show the inherent trade-off between these parameters around the edge of the ULVZ. Our method cannot directly constrain ULVZ height; tests show it underestimates ULVZ velocity reductions and overestimates ellipticity for thinner ULVZs due to neglecting mantle effects.
用Sdiff后标绘制核幔边界结构图:第一部分:方法和验证
超低速度带(Ultra-Low Velocity Zones, ULVZs)是位于地核-地幔边界上的地震速度极慢的地块。在这里,我们使用由ulvz引起的S核衍射相(Sdiff)的后驱物来靶向它们。我们使用这些后驱的旅行时间来制作概率映射,使用可逆跳跃马尔可夫链蒙特卡洛反演设置。对于正演模型,我们将之前为表面波多路径研究开发的二维波前跟踪(2DWT)软件扩展到核幔边界。2DWT能够模拟Sdiff后光标的完整多路径行为,并以几秒钟的顺序计算给定ULVZ输入速度结构的到达时间,而不是3D全波形合成所需的100个CPU小时。我们使用由2DWT产生的合成数据集以及3D全波形合成来验证该方法,使用由椭圆集合形成的参数化。我们还测试了理想的数据覆盖与更现实的覆盖情况。我们展示了ULVZ的大小和速度减小通常可以很好地恢复,我们的地图显示了这些参数在ULVZ边缘之间的内在权衡。我们的方法不能直接约束ULVZ高度;试验结果表明,由于忽略了地幔效应,该方法低估了极空空间的速度衰减,高估了较薄极空空间的椭圆率。
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来源期刊
Geophysical Journal International
Geophysical Journal International 地学-地球化学与地球物理
CiteScore
5.40
自引率
10.70%
发文量
436
审稿时长
3.3 months
期刊介绍: Geophysical Journal International publishes top quality research papers, express letters, invited review papers and book reviews on all aspects of theoretical, computational, applied and observational geophysics.
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