An adjoint-based optimization method for jointly inverting heterogeneous material properties and fault slip from earthquake surface deformation data

IF 2.8 3区 地球科学 Q2 GEOCHEMISTRY & GEOPHYSICS
S Puel, T W Becker, U Villa, O Ghattas, D Liu
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Abstract

Summary Analysis of tectonic and earthquake-cycle associated deformation of the crust can provide valuable insights into the underlying deformation processes including fault slip. How those processes are expressed at the surface depends on the lateral and depth variations of rock properties. The effect of such variations is often tested by forward models based on a priori geological or geophysical information. Here, we first develop a novel technique based on an open-source finite-element computational framework to invert geodetic constraints directly for heterogeneous media properties. We focus on the elastic, coseismic problem and seek to constrain variations in shear modulus and Poisson’s ratio, proxies for the effects of lithology and/or temperature and porous flow, respectively. The corresponding non-linear inversion is implemented using adjoint-based optimization that efficiently reduces the cost function that includes the misfit between the calculated and observed displacements and a penalty term. We then extend our theoretical and numerical framework to simultaneously infer both heterogeneous Earth’s structure and fault slip from surface deformation. Based on a range of 2-D synthetic cases, we find that both model parameters can be satisfactorily estimated for the megathrust setting-inspired test problems considered. Within limits, this is the case even in the presence of noise and if the fault geometry is not perfectly known. Our method lays the foundation for a future reassessment of the information contained in increasingly data-rich settings, e.g. geodetic GNSS constraints for large earthquakes such as the 2011 Tohoku-oki M9 event, or distributed deformation along plate boundaries as constrained from InSAR.
基于伴随优化的非均质材料与断层滑动地震地表变形联合反演方法
对地壳构造和地震旋回相关变形的分析可以对包括断层滑动在内的潜在变形过程提供有价值的见解。这些过程如何在地表表现取决于岩石性质的横向和深度变化。这种变化的影响通常是通过基于先验地质或地球物理信息的正演模型来检验的。在这里,我们首先开发了一种基于开源有限元计算框架的新技术,用于直接反演异构介质属性的大地测量约束。我们专注于弹性、同震问题,并寻求约束剪切模量和泊松比的变化,分别代表岩性和/或温度和孔隙流动的影响。相应的非线性反演是使用基于伴随的优化来实现的,该优化有效地减少了代价函数,其中包括计算和观测位移之间的不拟合以及惩罚项。然后,我们扩展了我们的理论和数值框架,同时从地表变形推断地球的非均匀结构和断层滑动。基于一系列二维综合案例,我们发现两个模型参数都可以令人满意地估计出所考虑的大推力设置启发试验问题。在一定范围内,即使在存在噪声和断层几何形状不完全已知的情况下也是如此。我们的方法为未来重新评估数据日益丰富的环境中包含的信息奠定了基础,例如,2011年东北木M9事件等大地测量GNSS大地震的约束,或InSAR约束下沿板块边界的分布变形。
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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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