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Ultrasonic treatment of ultrafine-grained titanium

•Ultrasonic treatment of ultrafine-grained Ti processed by high pressure torsion was performed.•No changes in microhardness and microdeformation were revealed.•Validation of the experimental data was made using molecular dynamics simulations.•Relaxation of the GBs in Ti requires much higher strains...

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Published in:	Physics letters. A 2020-12, Vol.384 (35), p.126906, Article 126906
Main Authors:	Murzaev, R.T., Bachurin, D.V., Mukhametgalina, A.A., Murzinova, M.A., Nazarov, A.A.
Format:	Article
Language:	English
Subjects:	Mechanical properties Molecular dynamics simulations Ultrafine-grained titanium Ultrasonic treatment
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description	•Ultrasonic treatment of ultrafine-grained Ti processed by high pressure torsion was performed.•No changes in microhardness and microdeformation were revealed.•Validation of the experimental data was made using molecular dynamics simulations.•Relaxation of the GBs in Ti requires much higher strains than those that can be achieved experimentally. Ultrasonic treatment of commercially pure ultrafine-grained Ti processed by high pressure torsion is performed. Measurements show no significant relaxation of the structure and no changes in both microhardness and microdeformation even at the maximum possible ultrasound amplitudes. Validation of the experimental observations is made with the help of molecular dynamics simulation of bicrystals containing non-equilibrium grain boundaries. It turns out that the relaxation of grain boundaries in Ti requires much higher strain amplitudes than those that can be achieved experimentally. The results are compared with those obtained previously for pure ultrafine-grained Ni, where a significant relaxation of the microstructure has been observed.
doi_str_mv	10.1016/j.physleta.2020.126906
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Ultrasonic treatment of commercially pure ultrafine-grained Ti processed by high pressure torsion is performed. Measurements show no significant relaxation of the structure and no changes in both microhardness and microdeformation even at the maximum possible ultrasound amplitudes. Validation of the experimental observations is made with the help of molecular dynamics simulation of bicrystals containing non-equilibrium grain boundaries. It turns out that the relaxation of grain boundaries in Ti requires much higher strain amplitudes than those that can be achieved experimentally. 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Ultrasonic treatment of commercially pure ultrafine-grained Ti processed by high pressure torsion is performed. Measurements show no significant relaxation of the structure and no changes in both microhardness and microdeformation even at the maximum possible ultrasound amplitudes. Validation of the experimental observations is made with the help of molecular dynamics simulation of bicrystals containing non-equilibrium grain boundaries. It turns out that the relaxation of grain boundaries in Ti requires much higher strain amplitudes than those that can be achieved experimentally. The results are compared with those obtained previously for pure ultrafine-grained Ni, where a significant relaxation of the microstructure has been observed.</abstract><pub>Elsevier B.V</pub><doi>10.1016/j.physleta.2020.126906</doi><orcidid>https://orcid.org/0000-0001-8995-211X</orcidid></addata></record>
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subjects	Mechanical properties Molecular dynamics simulations Ultrafine-grained titanium Ultrasonic treatment
title	Ultrasonic treatment of ultrafine-grained titanium
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