Introduction to High-Temperature Superconductivity for Solid State Chemists

TL;DR

This paper provides an accessible introduction to high-temperature superconductivity for solid state chemists, focusing on copper oxides, their mechanisms, and strategies to enhance Tc, aiming to inspire further discovery of room-temperature superconductors.

Contribution

It offers a simplified, physics-based overview of high-Tc superconductivity tailored for chemists and classifies materials by their superconducting mechanisms, emphasizing copper oxides.

Findings

High Tc in copper oxides is linked to unconventional mechanisms.

Material dependence of Tc is significant and complex.

Strategies for increasing Tc are discussed.

Abstract

Superconductivity is one of the most amazing properties that metallic conductors exhibit. Electrical resistance is completely eliminated below the critical temperature (Tc), which is the most important parameter in superconductivity. Since the discovery of copper oxide superconductors 39 years ago, many solid state chemists have made significant contributions to the field by discovering new compounds and producing high-quality samples for physical measurements. However, superconductivity research remains challenging for most solid state chemists because it requires knowledge of complicated solid state physics. This manuscript aims to provide a simple, intuitive introduction to superconductivity using only fundamental physics concepts that solid state chemists are familiar with. The author investigates a wide range of materials and classifies them according to the superconductivity mechanisms that may drive them. Specifically focusing on a series of copper oxide superconductors with the highest Tc at ambient conditions, the remarkable material dependence of Tc and the underlying, unconventional superconductivity mechanism that leads to the high Tc are thoroughly examined. Although our understanding of cuprate superconductivity is still fragmented, the author believes that once the branches and leaves are removed, the story will be fairly simple, similar to the phonon-based superconductivity mechanism revealed by the BCS theory. Furthermore, potential strategies for raising the Tc of cuprates and other superconductors are discussed. The author hopes that this article will pique interest in superconductors in young solid state chemists and encourage them to pursue the discovery of still unknown and unexplored room-temperature superconductors in the future.