This has been seen experimentally. Yet their behaviour remains a mystery. The repulsive forces between the electrons in these materials are much stronger than in low-temperature superconductors: so how do particles with the same charge overcome these forces and manage to pair-up and to transport current as it happens in "traditional" superconductors- A team of researchers of SISSA in Trieste in collaboration with the Vienna University of Technology have found a possible, surprising answer.
Low-temperature superconductors
"Superconductors are interesting materials because they hide many mysteries that remain unsolved and, at the same time, they offer an incredible application potential," explain Laura Fanfarillo, Angelo Valli and Massimo Capone, authors of the research. They are chemical compounds which, below a critical temperature, conduct electricity without any resistance, so without heat dissipation. It is easy to imagine their potential in the technological field. Were it not that for many of them, so-called "low-temperature superconductors", superconductivity appears at temperatures very close to the absolute zero, making their use complicated and very costly. However, there are also high-temperature superconductors, such as bad metals, whose critical temperature, although well below zero, require a much less complicated and expensive cooling. For this reason, these materials are considered to be the most interesting superconductors to explore in order to shed light on the physical characteristics that make them so special.
"And yet they move (together)"
The researchers explain "In low-temperature superconductors we know that superconductivity is the result of the pairing of electrons that overcome the repulsion due to their negative charge thanks to a "mediator". Once organised into pairs the electrons begin to move coherently and transport electric current without encountering any resistance. In bad metals, the Coulomb repulsion, which the electrons are subject to, is much stronger than in traditional metals. This repulsion, in theory, should prevent even more decisively the formation of these pairs and the transport of the supercurrent." This is where the question arises: "Since we know that the pairing between electrons is the mechanism at the base of superconduction and that, at least in this case, there is a mediator, it remains to be understood how bad metals are such good superconductors. With our calculations, we have tried to shed light on this intriguing mystery".
Quasiparticles to conduct electricity
What the scientists discovered is that it is precisely the characteristics that, at a superficial glance, would make them the worst possible candidates, that turn these materials into such powerful superconductors. In these materials, the electrons transform into peculiar "quasiparticles" whose characteristics are actually much more compatible with pairing, thereby justifying their experimental behaviour. However, it does not end here: "In this work we also demonstrated that a new type of bad metal characterised by a peculiar type of repulsion, called "Hund's metal", opens up interesting prospects in the field of superconductivity". "Our results" conclude the scientists "accurately and elegantly explain a quantity of experimental evidence in the class of ferrous superconductors, a relatively new type of material discovered in 2008, but whose unprecedented properties are still a field of investigation full of questions for scientists".