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Magnetic fluctuations in the UTe2 superconductor

The compound UTe2 opens a breach in the theory of superconductivity by correlated electrons. In this study, researchers at our laboratory finely analyze the magnetic fluctuations in the core of the material, using neutron scattering. These characteristics reveal original links between magnetism and superconductivity.

Published on 17 March 2022
The superconductivity of materials, i.e. the ability to conduct electric current without loss of energy, is attracting the attention of fundamental and applied research. In a well-understood behavior, most metals become superconductors at very low temperatures, and this state is incompatible with magnetic properties. The discovery of new families of materials is challenging the understanding of the mechanisms of superconductivity. Indeed, researchers have discovered materials that can be both magnetic and superconducting, such as certain uranium-based alloys..

Discovered in 2018, the superconductivity of the compound UTe2 has the remarkable property of being robust to the magnetic field, because the electrons gather in pairs with their spin oriented in the same direction. This superconductivity is of the "spin triplet" type. Researchers at our laboratory have performed neutron scattering experiments at the Institut Laue Langevin in Grenoble to measure the magnetic fluctuations of UTe2 at the atomic level. A detailed analysis has allowed to highlight the local ferromagnetic coupling of Uranium atoms in the middle of dominant antiferromagnetic fluctuations. This coupling is located within the crystallographic structure of UTe2, between the two closest uranium atoms forming a ladder composed of legs and rungs (Figure). The hypothesis is that this ferromagnetic coupling is very favorable to the realization of the "spin triplet" state of the electron pairs.

Later, the researchers will study precisely the link between the ferromagnetic ladder rungs and superconductivity. The characteristics obtained by neutron scattering are essential information, at the microscopic scale, to build a theoretical description of the superconducting behavior of UTe2. This fundamental knowledge will allow a more general understanding of unconventional superconductivity.

Figure: Spectrum of neutron scattering in UTe2.
The magnetic fluctuations describe a sinusoidal curve. The maximum of the curve is due to the ferromagnetic coupling of the uranium atoms (red arrows: magnetic moment) which form the rungs of a ladder.

Collaboration: Laboratoire National des Champs Magnétiques Intenses de Toulouse (LNCMI), Institut Laue Langevin de Grenoble (ILL), Tohoku University and Japan Atomic Energy Agency (JAEA), Japan.

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