Some Features of Cleavage Cracks in Rocks and Metals

Reviews on Advanced Materials and Technologies Pub Date : 2023-01-01 DOI:10.17586/2687-0568-2023-5-3-9-23

Peter Panfilov, Roman Korovin, Maxim Mezenov, Dmitry Zaytsev, Nikita Efremovtsev

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Abstract

The cracking of some rocks, namely granite, serpentinite and sandstone under tensile stress is examined in details. Brazilian testing or diametral compression, three points bending and explosion testing are used as the loading schemes in air at room temperature. Morphology of cracks in the model rocks are compared with cracks in silicon crystals, as the standard of a brittle crack, with cleavage cracks in iridium single crystals and with cracks in gallium-covered aluminum single crystals. The comparison of cracks between themselves has shown that there is additional channel for stress accommodation in the model rocks. This channel does not lead to transformation of a rock into a macroscopically ductile material, but it causes the arrest of the dangerous crack in it under tensile stress. Its influence causes transition from the brittle crack to the pore-like crack on the microscopic scale. The most probable mechanism of this transition is the dislocation emission from crack, which becomes possible in such a natural covalent solid as a rock due to Rehbinder's effect.

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岩石和金属中解理裂纹的一些特征

详细研究了花岗岩、蛇纹岩和砂岩等岩石在拉应力作用下的开裂。采用巴西试验或直径压缩试验、三点弯曲试验和爆炸试验作为室温空气加载方案。将模型岩石中的裂纹形态与硅晶体中的裂纹作为脆性裂纹的标准，与铱单晶中的解理裂纹和镓包铝单晶中的裂纹进行了比较。裂缝之间的对比表明，在模型岩石中存在额外的应力调节通道。这个通道不会导致岩石转变为宏观上的延展性材料，但它会在拉应力下阻止岩石中的危险裂缝。它的影响导致微观上由脆性裂纹向孔洞状裂纹转变。这种转变最可能的机制是裂纹的位错发射，这在像岩石这样的天然共价固体中由于Rehbinder效应而成为可能。

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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Reviews on Advanced Materials and Technologies

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