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Violation of the Taylor relation under high-energy external influences

Russian version

DOI: 10.21883/PSS.2022.08.54620.340

Malashenko V. V. ^1,2

¹Donetsk Institute for Physics and Engineering, Donetsk, Ukraine
²Donetsk National University, Donetsk, Ukraine

Email: malashenko@donfti.ru

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Abstract
References
Статистика просмотров

The motion of an edge dislocation ensemble in a binary alloy under high strain rate deformation is theoretically analyzed. Within the framework of the theory of dynamic interaction of defects (DID) an analytical expression for the dependence of the dynamic yield stress on the dislocation density is obtained. The conditions for the violation of the Taylor relation under high-energy external influences are determined. The experimentally observed nonmonotonic dependence of the dynamic yield strength on the dislocation density is explained. The minimum of this dependence is due to the competition between the influence of various structural defects on moving dislocations. This minimum takes place during the transition from the dominance of dynamic drag by one type of defects to the dominance of another type defects. Keywords: dislocations, high strain rate deformation, defects, Guinier-Preston zones, alloys.

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