Lattice Parameters Guide Superconductivity in Iron-Arsenides

TL;DR

This paper reviews how lattice parameter changes in iron-arsenide superconductors influence their superconducting properties, providing insights to guide future material synthesis and theoretical understanding.

Contribution

It systematically analyzes lattice parameter trends in iron-arsenide superconductors, highlighting the role of c-lattice parameter reduction in inducing superconductivity.

Findings

Superconductors have nearly tetragonal structures with a-lattice close to 4 Å.

Superconductivity strongly depends on changes in the c-lattice parameter.

A decrease in c-lattice parameter is associated with the onset of superconductivity.

Abstract

The discovery of superconducting materials has led to their use in technological marvels such as magnetic-field sensors in MRI machines, powerful research magnets, short transmission cables, and high-speed trains. Despite such applications, the uses of superconductors are not widespread because they function much below room-temperature, hence the costly cooling. Since the discovery of Cu- and Fe-based high-temperature superconductors (HTS), much intense effort has tried to explain and understand the superconducting phenomenon. While no exact explanations are given, several trends are reported in relation to the materials basis in magnetism and spin excitations. In fact, most HTS have antiferromagnetic undoped 'parent' materials that undergo a superconducting transition upon small chemical substitutions in them. As it is currently unclear which 'dopants' can favor superconductivity, this manuscript investigates crystal structure changes upon chemical substitutions, to find clues in lattice parameters for the superconducting occurrence. We review the chemical substitution effects on the crystal lattice of iron-arsenide-based crystals (2008 to present). We note that (a) HTS compounds have nearly tetragonal structures with a-lattice parameter close to 4 A, and (b) superconductivity can depend strongly on the c-lattice parameter changes with chemical substitution. For example, a decrease in c-lattice parameter is required to induce 'in-plane' superconductivity. The review of lattice parameter trends in iron-arsenides presented here should guide synthesis of new materials and provoke theoretical input, giving clues for HTS.