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Philosophical Magazine Volume 97, 2017 - Issue 12
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Part A: Materials Science

Inherent hydrostatic tensile strength of tungsten nanocrystals

Sergiy KotrechkoDepartment of Materials Strength and Fracture Physics, G. V. Kurdyumov Institute for Metal Physics, National Academy of Sciences of Ukraine, Kyiv, Ukraine
,
Oleksandr OvsjannikovDepartment of Materials Strength and Fracture Physics, G. V. Kurdyumov Institute for Metal Physics, National Academy of Sciences of Ukraine, Kyiv, Ukraine
,
Tatjana MazilovaDepartment of Low Temperatures and Condensed State, National Science Center, Kharkov Institute for Physics and Technology, National Academy of Sciences of Ukraine, Kharkov, Ukraine
,
Igor MikhailovskijDepartment of Low Temperatures and Condensed State, National Science Center, Kharkov Institute for Physics and Technology, National Academy of Sciences of Ukraine, Kharkov, Ukraine
,
Evgenij SadanovDepartment of Low Temperatures and Condensed State, National Science Center, Kharkov Institute for Physics and Technology, National Academy of Sciences of Ukraine, Kharkov, Ukraine
&
Nataliya StetsenkoDepartment of Materials Strength and Fracture Physics, G. V. Kurdyumov Institute for Metal Physics, National Academy of Sciences of Ukraine, Kyiv, UkraineCorrespondence[email protected]
[email protected]
Pages 930-943 | Received 15 Oct 2016, Accepted 17 Jan 2017, Published online: 08 Feb 2017
 
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Abstract

Experimental value of strength of nano-sized crystal under uniform triaxial (hydrostatic) tension was obtained for the first time. Strength was measured by in situ high-field mechanical testing of tungsten defect-free nano-sized specimen carried out inside a field-ion microscope. At temperature 77 K, this strength is 28 ± 3 GPa. Based on the MD simulation findings, it is ascertained that under these conditions the instability of an entire nano-sized specimen (global instability) is initiated by the Bain transition within a local region of the specimen. The model of ‘fluctuation-induced Bain transition’ is offered. Within the framework of the model proposed, it is exhibited that possibility of realisation of such local Bain transition under global hydrostatic tension is due to the fluctuation of local tensile stresses. In general, it is shown that fluctuation-induced Bain transition governs the level of the strength of nano-sized bcc crystals under hydrostatic tension.

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