Specific heat analyses on optical-phonon-derived uniaxial negative thermal expansion system TrZr2 (Tr = Fe and Co1-xNix)

Abstract

Recently, huge uniaxial negative thermal expansion (NTE) along a c-axis has been observed in transition-metal (Tr) zirconides TrZr2 with a tetragonal CuAl2-type structure. In a recent study on FeZr2 [M. Xu et al., Nat. Commun. 14, 4439 (2023)], the importance of optical phonons to the emergence of the c-axis NTE in FeZr2 has been proposed. In this study, the physical properties of TrZr2 (Tr = Fe and Co1-xNix) have been studied by specific heat, sound velocity measurements, and theoretical phonon calculations to discuss the importance of optical phonons to the emergence of the c-axis NTE in CoZr2 and FeZr2. From analyses of lattice specific heat, we found that Ni substitution results in a systematic decrease in oscillator strength for the Einstein modes with 8.74 meV (CoZr2). From phonon calculations, the low-energy optical phonon branches at the point were observed for CoZr2 and FeZr2 with c-axis NTE, but not in NiZr2 with positive thermal expansion. The enhancement of phonon density of states near the above-mentioned optical phonon energy in CoZr2 and FeZr2 is consistent with the specific heat analyses. We propose the importance of the low-energy optical phonons to the emergence of the c-axis NTE in TrZr2.