Nonlinear relaxation in geomaterials: New results

Proc. Meet. Acoust. Pub Date : 2018-11-06 DOI:10.1121/2.0000910

L. Ostrovsky, A. Lebedev, S. Manakov, Jérémy Rivière, P. Shokouhi, R. Guyer, M. S. Geesey, P. Johnson

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引用次数: 3

Abstract

Numerous acoustic experiments demonstrate that in media with a complex structure, such as rock, the elastic response is characterized by (i) a decrease in the material modulus during wave excitation, typically with a hysteresis (fast nonlinear dynamics), and (ii) long-time recovery to the original equilibrium modulus (slow dynamics). Here, a physical model of a granular material with an inter-grain contact potential having one or more metastable wells suggested earlier is significantly developed to include a non-logarithmic stage and the joint action of excitation and recovery. Theoretical results are compared with our experimental data.Numerous acoustic experiments demonstrate that in media with a complex structure, such as rock, the elastic response is characterized by (i) a decrease in the material modulus during wave excitation, typically with a hysteresis (fast nonlinear dynamics), and (ii) long-time recovery to the original equilibrium modulus (slow dynamics). Here, a physical model of a granular material with an inter-grain contact potential having one or more metastable wells suggested earlier is significantly developed to include a non-logarithmic stage and the joint action of excitation and recovery. Theoretical results are compared with our experimental data.

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岩土材料的非线性松弛:新结果

大量声学实验表明，在具有复杂结构的介质中，如岩石，弹性响应的特征是:(i)在波激励期间材料模量下降，通常具有滞后(快速非线性动力学)，以及(ii)长时间恢复到原始平衡模量(慢动力学)。在这里，具有先前提出的具有一个或多个亚稳井的颗粒间接触电位的颗粒材料的物理模型被显著地发展为包括非对数阶段和激发和恢复的联合作用。理论结果与实验数据进行了比较。大量声学实验表明，在具有复杂结构的介质中，如岩石，弹性响应的特征是:(i)在波激励期间材料模量下降，通常具有滞后(快速非线性动力学)，以及(ii)长时间恢复到原始平衡模量(慢动力学)。在这里，具有先前提出的具有一个或多个亚稳井的颗粒间接触电位的颗粒材料的物理模型被显著地发展为包括非对数阶段和激发和恢复的联合作用。理论结果与实验数据进行了比较。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Proc. Meet. Acoust.

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