Microstructure and Structural Phase Transitions in Iron-Based Superconductors

TL;DR

This review discusses how microstructural features and structural phase transitions in iron-based superconductors influence their physical properties, highlighting recent research on various structural phenomena and their relation to superconductivity.

Contribution

It provides a comprehensive overview of microstructural features and phase transitions in Fe-based superconductors, emphasizing recent experimental findings and their implications.

Findings

Structural features vary across different superconducting families.

Local distortions and inhomogeneities are linked to superconductivity.

Fe-vacancy order and phase separation are key in K0.8Fe1.6+xSe2.

Abstract

Crystal structures and microstructural features, such as structural phase transitions, defect structures, chemical and structural inhomogeneities, are known to have profound effects on the physical properties of superconducting materials. Recently, a large amount of works on the structural properties of Fe-based high-Tc superconductors have been published. This review article will mainly focus on typical microstructural features in samples that have been well characterized by physical measurements. (a) Certain common structural features are discussed. In particular, crystal structural features for different superconducting families, local structural distortions in the Fe2Pn2 (Pn=P, As, Sb) or Fe2Ch2 (Ch=S, Se, Te) blocks, and structural transformations in the 122 system. (b) In FeTe(Se) (11-family), the superconductivity, chemical and structural inhomogeneities are investigated and discussed in correlation with superconductivity. (c) In K0.8Fe1.6+xSe2 system, we focus on typical compounds with emphasis on Fe-vacancy order and phase separations. The microstructural features in other superconducting materials are also briefly discussed.