Stabilization of Martensite and Austenite Phases and Realization of Two-way Martensitic Transition in Co-Ni-Ga Ferromagnetic Shape Memory Alloy Nanoparticles

TL;DR

This study synthesizes Co-Ni-Ga alloy nanoparticles demonstrating reversible martensitic and austenitic phase transitions with tunable magnetic properties, highlighting their potential for advanced nanoactuator applications.

Contribution

It reports the first observation of two-way martensitic transition in Co-Ni-Ga nanoparticles with controlled phase and magnetic properties.

Findings

Reversible martensitic and austenitic phases confirmed by temperature-dependent XRD.

Nanoparticles exhibit tunable magnetic saturation from 2.9 to 15.3 emu/g.

Presence of gamma phase does not hinder the martensitic transition.

Abstract

Three sets of Co-Ni-Ga alloy nanoparticles have been synthesized by a template-free chemical route. Structural, morphological, shape memory, and magnetic properties of room temperature martensite (M) phase, dual (M + secondary $\gamma$) phase and austenite (A) phase Co-Ni-Ga nanoparticles are reported. Temperature-dependent XRD analysis revealed that $Co_{36}Ni_{36}Ga_{28}$ nanoparticles exhibiting a single M phase at room temperature, completely transform to A phase at $\sim1000$ K. Upon cooling to room temperature, the A phase transforms back to single M phase, confirming the two-way martensitic transition in Co-Ni-Ga nanoparticles. Structural analysis shows that the $\gamma$-phase does not influence the martensitic transition of bi-phasic (M + $\gamma$) $Co_{41}Ni_{34}Ga_{25}$ nanoparticles. These nanoparticles display saturation magnetization ranging from 2.9 emu/g to 15.3 emu/g at room temperature. The $\gamma$ phase could be introduced in A phase $Co_{44}Ni_{26}Ga_{30}$ nanoparticles when heated up to 1073 K. Curie temperatures of A and M phases are higher than the martensitic transition temperatures in all the samples, qualifying them as ferromagnetic shape memory alloy nanoparticles. Observation of M $\leftrightarrow$ A phase transition, Co-Ni-Ga nanoparticles with tunable magnetic properties make them excellent candidates for low and high temperature nanoactuators and other ferromagnetic shape memory applications.