A research team, led by Brown University physicists, has found a new way to precisely probe the nature of the superconducting state in magic-angle graphene. The technique enables researchers to manipulate the repulsive force – the Coulomb interaction – in the system. In their recent study, the researchers showed that magic-angle superconductivity grows more robust when Coulomb interaction is reduced, which could be an important piece of information in understanding how this superconductor works.
“This is the first time anyone has demonstrated that you can directly manipulate the strength of Coulomb interaction in a strongly correlated electronic system,” said Jia Li, an assistant professor of physics at Brown and corresponding author of the research. “Superconductivity is driven by the interactions between electrons, so when we can manipulate that interaction, it tells us something really important about that system. In this case, demonstrating that weaker Coulomb interaction strengthens superconductivity provides an important new theoretical constraint on this system.”
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Graphene applications, Conductors, Technical / Research