Tension-compression asymmetry in superelasticity of SrNi2P2 single crystals and the influence of low temperatures

TL;DR

This study investigates the tension-compression asymmetry in superelasticity of SrNi2P2 single crystals and how low temperatures influence these structural transitions, revealing potential for elastocaloric applications.

Contribution

It uncovers the asymmetric superelastic behavior and temperature dependence in SrNi2P2, combining experimental and theoretical insights into its unique structural transitions.

Findings

Tension and compression induce opposite structural transitions in SrNi2P2.

Superelasticity exhibits asymmetry with respect to temperature and loading direction.

Potential for opposite elastocaloric effects under tension and compression.

Abstract

ThCr2Si2-type intermetallic compounds are known to exhibit superelasticity associated with structural transitions through lattice collapse and expansion. These transitions occur via the formation and breaking of Si-type bonds, respectively, under uniaxial loading along the [0 0 1] direction. Unlike most ThCr2Si2-type intermetallic compounds, which have either an uncollapsed tetragonal structure or a collapsed tetragonal structure, SrNi2P2 possesses a third type of collapsed structured: a one-third orthorhombic structure, for which one expects the occurrence of unique structural transitions and superelastic behavior. In this study, uniaxial compression and tension tests were conducted on micron-sized SrNi2P2 single crystalline columns at room temperature, 200K, and 100K, to investigate the influence of loading direction and temperature on the superelasticity of SrNi2P2. Experimental data and density functional theory calculations revealed the presence of tension-compression asymmetry in the structural transitions and superelasticity, as well as an asymmetry in their temperature dependence, due to the opposite superelastic process associated with compression (forming P-P bonds) and tension (breaking P-P bonds). Additionally, following thermodynamics, the observations suggest that this asymmetric superelasticity could lead to an opposite elastocaloric effect between compression and tension, which could be beneficial potentially in obtaining large temperature changes compared to conventional superelastic solids that show the same elastocaloric effect regardless of loading direction. These results provide an important fundamental insight into the structural transitions, superelasticity processes, and potential elastocaloric effects in SrNi2P2.