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防止摩擦不稳定系统中的失稳并诱导可控的慢滑移

Preventing Instabilities and Inducing Controlled, Slow-Slip in Frictionally Unstable Systems.

作者信息

Stefanou Ioannis, Tzortzopoulos Georgios

机构信息

Ecole Centrale de Nantes Université de Nantes CNRS GeM (Institut de Recherche en Génie Civil et Mécanique) Nantes France.

出版信息

J Geophys Res Solid Earth. 2022 Jul;127(7):e2021JB023410. doi: 10.1029/2021JB023410. Epub 2022 Jun 29.

DOI:10.1029/2021JB023410
PMID:35875412
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9290888/
Abstract

We propose a theory for preventing instabilities and inducing controlled, slow-slip in frictionally unstable systems, such as the Generalized-Burridge-Knopoff (GBK) model and seismic fault models. We exploit the dependence of friction on pressure and use it as a backdoor for altering the dynamics of the underlying dynamical system. We use the mathematical Theory of Control and, for the first time, we manage to (a) stabilize and restrict chaos in this kind of systems, (b) guarantee slow frictional dissipation and (c) tune the system toward desirable global asymptotic equilibria of lower energy. Our control approach is robust and does not require exact knowledge of the frictional or elastic behavior of the system. Numerical examples of control are given for a Burridge-Knopoff system and a strike-slip fault model obeying rate-and-state friction. GBK models are known to present Self-Organized Critical (SOC) behavior. Therefore, the presented methodology shows an additional example of SOC Control. Even though further developments are necessary before any practical application, we expect our methodology to inspire earthquake mitigation strategies regarding anthropogenic and/or natural seismicity.

摘要

我们提出了一种理论,用于防止摩擦不稳定系统中的不稳定性并诱导可控的慢滑,例如广义Burridge-Knopoff(GBK)模型和地震断层模型。我们利用摩擦力对压力的依赖性,并将其作为改变基础动力系统动力学的一个途径。我们运用控制理论,首次成功做到了:(a)在这类系统中稳定并限制混沌;(b)确保缓慢的摩擦耗散;(c)将系统调整至能量更低的理想全局渐近平衡态。我们的控制方法具有鲁棒性,不需要精确了解系统的摩擦或弹性行为。针对Burridge-Knopoff系统和服从速率-状态摩擦的走滑断层模型给出了控制的数值示例。已知GBK模型呈现自组织临界(SOC)行为。因此,所提出的方法展示了SOC控制的又一个实例。尽管在任何实际应用之前还需要进一步发展,但我们期望我们的方法能启发有关人为和/或自然地震活动的地震减灾策略。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/e63f/9290888/f444eba4f922/JGRB-127-0-g002.jpg
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