Optical conductivity of iron-based superconductors

TL;DR

This paper reviews the optical conductivity studies of iron-based superconductors, highlighting their electronic properties and discussing implications for understanding their unconventional superconductivity mechanism.

Contribution

It provides a comprehensive synthesis of seven years of optical-conductivity data, offering insights into the charge dynamics and pairing mechanisms in iron-based superconductors.

Findings

Optical conductivity reveals complex charge dynamics.

Data suggests unconventional pairing mechanisms.

Electronic structure differs from copper-based superconductors.

Abstract

The new family of unconventional iron-based superconductors discovered in 2006 immediately relieved their copper-based high-temperature predecessors as the most actively studied superconducting compounds in the world. The experimental and theoretical effort made in order to unravel the mechanism of superconductivity in these materials has been overwhelming. Although our understanding of their microscopic properties has been improving steadily, the pairing mechanism giving rise to superconducting transition temperatures up to 55 K remains elusive. And yet the hope is strong that these materials, which possess a drastically different electronic structure but similarly high transition temperatures compared to the copper-based compounds, will shed essential new light onto the several-decade-old problem of unconventional superconductivity. In this work we review the current understanding of the itinerant-charge-carrier dynamics in the iron-based superconductors and parent compounds largely based on the optical-conductivity data the community has gleaned over the past seven years using such experimental techniques as reflectivity, ellipsometry, and terahertz transmission measurements and analyze the implications of these studies for the microscopic properties of the iron-based materials as well as the mechanism of superconductivity therein.