Nature of CoCrFeMnNi/Fe and CoCrFeMnNi/Al Solid/Solid Interface

doi:10.1007/s40195-021-01325-y

Abstract

Abstract:

To shed light into the application potential of high-entropy alloys as “interlayer” materials for Al-steel solid-state joining, we investigated the nature of the CoCrFeMnNi/Fe and CoCrFeMnNi/Al solid/solid interfaces, focusing on the bonding behavior and phase components. Good metallurgical bonding without the formation of hard and brittle IMC can be achieved for CoCrFeMnNi/Fe solid/solid interface. In contrast to the formation of Al₅Fe₂ phase at the Fe/Al interface, Al₁₃Fe₄-type IMC, in which the Fe site is co-occupied equally by Co, Cr, Fe, Mn and Ni, dominates the CoCrFeMnNi/Al interface. Although the formation of IMC at the CoCrFeMnNi/Al interface is not avoidable, the thickness and hardness of the Al₁₃(CoCrFeMnNi)₄ phase formed at the CoCrFeMnNi/Al interface are significantly lower than the Al₅Fe₂ phase formed at the Fe/Al interface. The activation energies for the interdiffusion of Fe/Al and CoCrFeMnNi/Al static diffusion couple are 341.6 kJ/mol and 329.5 kJ/mol, respectively. Despite this similarity, under identical static annealing condition, the interdiffusion coefficient of the CoCrFeMnNi/Al diffusion couple is significantly lower than that of the Fe/Al diffusion couple. This is thus mainly a result of the reduced atomic mobility/diffusivity caused by the compositional complexity in CoCrFeMnNi high-entropy alloy.

Key words: High-entropy alloy, Microstructure, Metallurgical bonding, Interface

Zhongtao Li, Weidong Zhang, Zhenggang Wu. Nature of CoCrFeMnNi/Fe and CoCrFeMnNi/Al Solid/Solid Interface[J]. Acta Metallurgica Sinica (English Letters), 2021, 34(11): 1483-1491.

Figures/Tables 10

Fig. 1 Flowchart showing the typical procedure to apply HEA as Al-steel solid-state joining "interlayer" material, taking friction stir joining as an example

Fig. 2 Schematic showing the coating of CoCrFeMnNi on the Fe substrate and the diffusion bonding of Al with CoCrFeMnNi

Fig. 3 a Macrostructure of the generated Fe-CoCrFeMnNi-Al-Fe stacking; b BSE image of the CoCrFeMnNi layer obtained through the simultaneous sintering and coating

Fig. 4 a Macrostructure and b microstructure of the as-obtained CoCrFeMnNi/Fe interface and c the elemental distribution across the CoCrFeMnNi/Fe interface

Fig. 5 EBSD images showing a the IPF pole figure and b the phase map of the as-obtained CoCrFeMnNi/Fe interface

Fig. 6 a An overall view of the Fe-Al-CoCrFeMnNi sandwiched structure; magnified views of the obtained b Fe/Al interface and c CoCrFeMnNi/Al interface, the elemental distribution of which are presented in d e, respectively

Fig. 7 Selected area XRD patterns of a the Fe/Al interface and b the CoCrFeMnNi/Al interface

Fig. 8 EBSD images showing a, c the inverse pole figure images b, d the phase mappings of the as-obtained Fe/Al and CoCrFeMnNi/Al interfaces, respectively

Fig. 9 Thickness of the IMC layers at a the Fe/Al and b the CoCrFeMnNi/Al interfaces obtained under different temperatures and annealing time

Fig. 10 Arrhenius plot of interdiffusion coefficient D as a function of temperature for the Fe/Al and CoCrFeMnNi/Al binary diffusion couples

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