应力场处于剪切带，并形成主断层

IF 0.8 Q4 GEOCHEMISTRY & GEOPHYSICS

Geodynamics & Tectonophysics Pub Date : 2021-09-17 DOI:10.5800/gt-2021-12-3-0536

A. Lermontova

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引用次数: 1

摘要

采用解析逼近法，计算了不同剪切力相对位置下的应力场参数和剪切所需载荷。考虑到内摩擦角为30°，相邻剪切之间的距离超过特征剪切长度的0.7，我们估计了可能导致压裂的库仑应力。在剪切之间的区域，它低于抗剪强度值。这意味着，如果缺乏外部载荷的增加，则没有形成连接相邻剪切体的新裂缝的先决条件。如果剪之间的间距更近(即距离小于剪长度的0.7)，则在它们之间的区域超过抗剪强度，并且可以在那里发生新的剪并将里德尔剪相互连接。因此，在观察里德尔剪切的自然系统时，可以评估该系统在其当前状态下是否足够稳定，或者，在相邻剪切之间区域的库仑应力临界增加的情况下，平衡很容易被破坏，并且有可能在研究的走滑带中形成主断层。

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STRESS FIELD IN A SHEAR ZONE, AND FORMATION OF THE MAIN FAULT

Using the analytical approximation method, we calculated stress field parameters for cases with different relative positions of Riedel shears and loads required for shearing. Considering an internal friction angle of 30°, and the distance between adjacent shears exceeding 0.7 of the characteristic shear length, we estimated the Coulomb stress that can lead to fracturing. In the areas between the shears, it is below the shear strength value. This means that if an increase in the external load is lacking, there are no prerequisites for the formation of new fractures that may connect adjacent shears. If the shears are spaced closer to each other (i.e. at distances less than 0.7 of the shear length), the shear strength is exceeded in the areas between them, and new shears can occur there and connect the Riedel shears to each other. Therefore, in observations of a natural system of Riedel shears, it becomes possible to assess whether this system is sufficiently stable in its current status, or, in case of a critical increase in the Coulomb stress in the areas between adjacent shears, the equilibrium can be easily disturbed, and there is a possibility that the main fault forms in the strike-slip zone under study.

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来源期刊

Geodynamics & Tectonophysics GEOCHEMISTRY & GEOPHYSICS-

CiteScore

1.20

自引率

14.30%

发文量

审稿时长

24 weeks

期刊介绍： The purpose of the journal is facilitating awareness of the international scientific community of new data on geodynamics of continental lithosphere in a wide range of geolchronological data, as well as tectonophysics as an integral part of geodynamics, in which physico-mathematical and structural-geological concepts are applied to deal with topical problems of the evolution of structures and processes taking place simultaneously in the lithosphere. Complex geological and geophysical studies of the Earth tectonosphere have been significantly enhanced in the current decade across the world. As a result, a large number of publications are developed based on thorough analyses of paleo- and modern geodynamic processes with reference to results of properly substantiated physical experiments, field data and tectonophysical calculations. Comprehensive research of that type, followed by consolidation and generalization of research results and conclusions, conforms to the start-of-the-art of the Earth’s sciences.