Thermal modification of ZrCu metallic glass nanolaminates: Structure and mechanical properties

TL;DR

This study investigates how thermal treatments influence the atomic structure, stability, and mechanical properties of ZrCu metallic glass nanolaminates, revealing enhanced hardness and thermal stability through controlled annealing.

Contribution

It provides new insights into the effects of annealing on the structure and properties of ZrCu metallic glass nanolaminates, including atomic intermixing and crystallisation behavior.

Findings

Annealing up to 330°C maintains amorphous structure with atomic relaxation.

NLs show superior thermal stability, remaining amorphous up to 420°C.

Higher annealing temperatures increase hardness and elastic modulus.

Abstract

The effects of thermal treatments on metallic glass nanolaminates (NLs), with a composition of Zr$_{24}$Cu$_{76}$ and Zr$_{61}$Cu$_{39}$ and a bilayer period of 50 nm, were explored to control their mechanical properties through annealing-induced atomic structure modifications, structural relaxation, and partial crystallisation. Annealing treatments up to 330 {\deg}C ($T$ < $T_g$, the glass transition temperature) maintain the amorphous structure of the NLs, while inducing atomic structural relaxation, densification, and free volume annihilation, reducing the formation of corrugations on fracture surfaces. Atom probe tomography measurements reveal that annealing at 330 {\deg}C for 60 mins also causes intermixing between layers, altering their compositions to Zr$_{44}$Cu$_{56}$ and Zr$_{55}$Cu$_{45}$ with increased mixing enthalpy. Moreover, the NLs exhibit superior thermal stability against crystallisation compared to their monolithic counterparts, remaining amorphous up to 420 {\deg}C, while the monolithic Zr$_{24}$Cu$_{76}$ and Zr$_{61}$Cu$_{39}$ films are crystalline at 390 {\deg}C, as a result of chemical interdiffusion and the heterogeneous NL structure of delaying the onset of crystallisation. Annealing treatments $T$ > $T_g$ ($\sim$420 {\deg}C) induce partial crystallisation, forming Cu-Zr-based intermetallic and Zr-oxide phases, whereas annealing $T$ < $T_g$ (330 {\deg}C) retains a visible layer structure. Nanoindentation analyses show a progressive increase in elastic modulus and hardness for higher annealing temperatures as a result of structural relaxation and likely nanocrystal formation, with a maximum hardness equal to 7.6 $\pm$ 0.2 GPa obtained after heat treatment at 420 {\deg}C for 60 mins and exceeding the rule-of-mixtures. These results highlight the potential of thermal treatments to tailor the structural, mechanical and thermal properties of metallic glass NLs.