High resolution characterisation of microstructural evolution in Rb$_{x}$Fe$_{2-y}$Se$_{2}$ crystals on annealing

TL;DR

This study investigates how annealing affects the microstructure and superconducting properties of Rb$_x$Fe$_{2-y}$Se$_2$ crystals, revealing microstructural evolution, phase changes, and their correlation with electronic structure and superconductivity.

Contribution

It provides detailed microstructural and electronic characterization of Rb$_x$Fe$_{2-y}$Se$_2$ crystals during annealing, highlighting the relationship between phase evolution and superconducting properties.

Findings

Annealing causes coarsening of mesoscopic phases.

A third phase forms after annealing at 488K.

The minority phase's electronic structure correlates with superconductivity.

Abstract

The superconducting and magnetic properties of phase-separated A$_x$Fe$_{2-y}$Se$_2$ compounds are known to depend on post-growth heat treatments and cooling profiles. This paper focusses on the evolution of microstructure on annealing, and how this influences the superconducting properties of Rb$_x$Fe$_2-y$Se$_2$ crystals. We find that the minority phase in the as-grown crystal has increased unit cell anisotropy (c/a ratio), reduced Rb content and increased Fe content compared to the matrix. The microstructure is rather complex, with two-phase mesoscopic plate-shaped features aligned along {113} habit planes. The minority phase are strongly facetted on the {113} planes, which we have shown to be driven by minimising the volume strain energy introduced as a result of the phase transformation. Annealing at 488K results in coarsening of the mesoscopic plate-shaped features and the formation of a third distinct phase. The subtle differences in structure and chemistry of the minority phase(s) in the crystals are thought to be responsible for changes in the superconducting transition temperature. In addition, scanning photoemission microscopy has clearly shown that the electronic structure of the minority phase has a higher occupied density of states of the low binding energy Fe3d orbitals, characteristic of crystals that exhibit superconductivity. This demonstrates a clear correlation between the Fe-vacancy-free phase with high c/a ratio and the electronic structure characteristics of the superconducting phase.