Kinetic role of Cu content in reaction process, behavior and their relationship among Cu-Zr-C system

doi:10.1016/j.jmst.2019.05.034

Abstract

Abstract:

The influence of Cu content on the reaction process, reaction behavior and obtained products in the Cu-Zr-C system, as well as their relationships, were investigated. The results showed that ZrC was synthesized through the diffusion and dissolution of C into a Cu-Zr liquid. Increasing the Cu content enhanced the amount of Cu-Zr liquid formed at the early stage but decreased the amount of C atoms dissolving into the melt at unit time. Consequently, the ignition time initially decreased and then increased. Conversely, with an increased Cu content, the energy required for igniting the neighboring unreacted powders increased, while the heat released by the reaction and the dwell time of the compact at high temperatures decreased. These effects then resulted in the reduction of combustion wave velocity, combustion temperature and ZrC particle size. Furthermore, the synthesis of ZrC is a multistage process, which provides a nonuniform distributed ZrC particle size. The sub-μm ZrC particle reinforced Cu matrix composite was fabricated by adding a ZrC-Cu master alloy prepared through a self-propagating high-temperature synthesis reaction into liquid Cu.

Key words: Self-propagating high-temperature synthesis, Reaction process, Reaction behavior, Solidification

Qiaodan Hu, Xianrui Zhao, Siyu Sun, Hua Zheng, Sheng Cao, Jianguo Li, Mengxian Zhang. Kinetic role of Cu content in reaction process, behavior and their relationship among Cu-Zr-C system[J]. J. Mater. Sci. Technol., 2019, 35(10): 2375-2382.

Figures/Tables 10

Fig. 1. DSC curves of (a) Cu-0.69Zr system, (b) Cu-1.5Zr system and (c) Cu-2.5Zr system.

Fig. 2. XRD patterns for DSC products of (a) Cu-0.69Zr system, (b) Cu-1.5Zr system and (c) Cu-2.5Zr system quenched at different temperatures.

Fig. 3. Microstructures for DSC products of Cu-0.69Zr system quenched at different temperatures (a) 650 °C, (b) 910 °C, (c) 983 °C and (d) 1200 °C, respectively.

Fig. 4. DSC curves of (a) 50 wt% Cu-Zr-C system, (b) 30 wt% Cu-Zr-C system and (c) 20 wt% Cu-Zr-C system.

Fig. 5. XRD patterns for DSC products of (a) 50 wt% Cu-Zr-C system, (b) 30 wt% Cu-Zr-C system and (c) 20 wt% Cu-Zr-C system quenched at different temperatures.

Fig. 6. Microstructures for DSC products of 50 wt% Cu-Zr-C system quenched at different temperatures (a) 907 °C, (b) and (c) 1250 °C.

Fig. 7. Variations of the combustion temperature, wave velocity and ignition time with Cu content.

Fig. 8. XRD patterns of SHS products with different Cu content (a) 10 wt%, (b) 20 wt%, (c) 30 wt%, (d) 40 wt% and (e) 50 wt%, respectively.

Fig. 9. Microstructures of SHS products with different Cu content (a) 10 wt%, (b) 20 wt%, (c) 30 wt%, (d) 40 wt% and (e) 50 wt%, respectively.

Fig. 10. Microstructures of ZrC/Cu composites with different ZrC content (a) 0.1 wt%, (b) 0.2 wt% and (c) 0.3 wt%, respectively.

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