Abstract
In recent years, the methods of severe plastic deformation and rapid melt quenching have proven to be an effective tool for the formation of the unique properties of materials. The effect of high-pressure torsion (HPT) on the structure of the amorphous alloys of the quasi-binary TiNi–TiCu system with a copper content of more than 30 at.% produced by melt spinning technique has been analyzed using the methods of scanning electron microscopy, X-ray diffraction analysis, and differential scanning calorimetry (DSC). The structure examinations have shown that the HPT of the alloys with a Cu content ranging from 30 to 40 at.% leads to nanocrystallization from the amorphous state. An increase in the degree of deformation leads to a substantial change in the character of the crystallization reflected by the DSC curves of the alloys under study. The alloys containing less than 34 at.% Cu exhibit crystallization peak splitting, whereas the alloys containing more than 34 at.% Cu exhibit a third peak at lower temperatures. The latter effect suggests the formation of regions of possible low-temperature crystallization. It has been established that the HPT causes a significant decrease in the thermal effect of crystallization upon heating of the alloys with a high copper content relative to that of the initial amorphous melt quenched state.
Highlights
In accordance with modern trends in the development of science and technology, advanced industries urgently require “smart” multifunctional materials combining high-performance characteristics in addition to unique properties
In recent years, the methods of severe plastic deformation and rapid melt quenching have proven to be an effective tool for the formation of the unique properties of materials
The effect of high-pressure torsion (HPT) on the structure of the amorphous alloys of the quasi-binary TiNi–TiCu system with a copper content of more than 30 at.% produced by melt spinning technique has been analyzed using the methods of scanning electron microscopy, X-ray diffraction analysis, and differential scanning calorimetry (DSC)
Summary
In accordance with modern trends in the development of science and technology, advanced industries urgently require “smart” multifunctional materials combining high-performance characteristics in addition to unique properties. The design of high-speed (especially fast cyclic response) devices requires thin SME materials (thin ribbons, wires, or films) characterized by narrow hysteresis of martensitic phase transformations. The materials meeting such requirements include the alloys of the quasi-binary intermetallic TiNi–TiCu system with a copper content of more than 10 at.% [5]. The TiNiCu alloys with high copper content are brittle because of the TiCu phase formation near grain boundaries and, cannot be deformed into wire or ribbon upon hot or cold processing [6,7], which is necessary for the manufacture of thermal actuators. One of the best alternatives for overcoming the Materials 2019, 12, 2670; doi:10.3390/ma12172670 www.mdpi.com/journal/materials
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