Microstructure and mechanical evolution of Ti-based bulk metallic glass induced by deformation and isothermal annealing in supercooled liquid region

Microstructure and mechanical evolution of Ti-based bulk metallic glass induced by deformation and isothermal annealing in supercooled liquid region

•Thermally-deformed specimens have a denser structure and higher characteristic temperature than the annealed specimens.•Thermally-deformed and annealed specimens precipitated some nanocrystals with the size of approximately 10 nm at 648 K.•The yield and fracture strengths of the thermally-deformed...

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Bibliographic Details
Published in:Materials letters Vol. 307; p. 131038
Main Authors: Lv, J.W., Wei, C., Zhang, S., Shi, Z.L., Zhang, H.R., Yang, Y.J., Zhang, X.Y., Ma, M.Z.
Format: Journal Article
Language:English
Published: Amsterdam Elsevier B.V 15-01-2022
Elsevier BV
Subjects:
Amorphous materials
Deformation effects
Isothermal annealing
Materials science
Mechanical properties
Mechanical property
Metallic glasses
Microstructure
Nanocrystals
Plastic properties
Room temperature
Temperature
Thermal deformation
Titanium
Amorphous materials
Microstructure
Mechanical property
Thermal deformation
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Summary:•Thermally-deformed specimens have a denser structure and higher characteristic temperature than the annealed specimens.•Thermally-deformed and annealed specimens precipitated some nanocrystals with the size of approximately 10 nm at 648 K.•The yield and fracture strengths of the thermally-deformed specimen are higher than that of the annealed specimen.•Both the 648 K-deformed and 648 K-annealed specimens exhibited brittle fracture characteristics. The effects of deformation and isothermal annealing in supercooled liquid region on the microstructure and room-temperature mechanical properties of the Ti33Zr30Cu9Ni5.5Be22.5 bulk metallic glass were systematically investigated. The results indicated that the thermally-deformed specimens exhibited denser structures and higher characteristic temperatures (Tg and Tx) than the annealed specimens at the corresponding temperature; however, this difference gradually decreased as the experimental temperature increased. Further, the thermally-deformed specimens exhibited higher yield and fracture strengths than the annealed specimens, whereas they exhibited similar plasticity. The deformed and annealed specimens precipitated some nanocrystals with a size of approximately 10 nm when the experimental temperature increased to 648 K, causing the rapid deterioration of their plasticity.
ISSN:0167-577X
1873-4979
DOI:10.1016/j.matlet.2021.131038