Structural evolution and metastable phase formation in Ni-W multilayers upon ion irradiation

Abstract

A crystal-to-amorphous structural transition was induced in the Ni25W75 and Ni35W65 multilayers by ion irradiation at room temperature. More interestingly, prior to complete amorphization, a sequential disordering of first Ni and then W crystalline lattices was observed in the Ni25W75 sample with increasing ion dose. Such sequence in disordering is attributed to the difference in melting points between the two constituent metals. In another two multilayered samples with overall compositions of Ni60W40 and Ni78Nb22, ion irradiation under similar conditions resulted in the formation of two Ni-based fcc solid solutions, respectively. In comparison, the same Ni-based fcc solid solution was formed in the Ni35W65 multilayered sample upon solid-state reaction at 500 °C. Solid-state reaction at 550 °C resulted in the formation of a new W-rich metastable hcp phase in the Ni25W75 multilayered sample and the bcc–hcp transition was thought to be realized through a shearing mechanism. A Gibbs free-energy diagram, including the free-energy curves of the newly formed metastable crystalline phases, of the Ni-W system was calculated based on Miedema’s model and it can give a reasonable explanation of the observed sequential disordering. The calculated results also showed that the free-energy difference between the amorphous and metastable crystalline phases was quite small, leading to a situation that the phase selection, namely which phase was more favored to be formed eventually than its competitors, was influenced or even determined by the kinetics involved in the respective processes. Besides, the growth kinetics of the MX phases was also discussed.