Probing the Meissner effect in pressurized bilayer nickelate superconductors using diamond quantum sensors

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Abstract

Abstract Recent reports on the signatures of high-temperature superconductivity with a critical temperature Tc close to 80 K have triggered great research interest and extensive follow-up studies1-8. Although zero-resistance state has been successfully achieved under improved hydrostatic pressure conditions3,9, there is no clear evidence of superconducting diamagnetism in pressurized La3Ni2O7-δ due to the low superconducting volume fraction and limited magnetic measurement techniques under high pressure conditions10. Here, using shallow nitrogen-vacancy centers implanted on the culet of diamond anvils as in-situ quantum sensors, we observe convincing evidence for the Meissner effect in polycrystalline samples La3Ni2O7-δ and La2PrNi2O7: the magnetic field expulsion during both field cooling and field warming processes. The correlated measurements of Raman spectra and NV-based magnetic imaging indicate an incomplete structural transformation related to the displacement of oxygen ions emerging in the non-superconducting region. Furthermore, comparative experiments on different pressure transmitting media (silicone oil and KBr) and nickelates (La3Ni2O7-δ and La2PrNi2O7) reveal that an improved hydrostatic pressure conditions and the substitution of La by Pr in La3Ni2O7-δ can dramatically increase the superconductivity. Our work clarifies the controversy about the Meissner effect of bilayer nickelate and contributes to a deeper understanding of the mechanism of nickelate high-temperature superconductors.

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last seen: 2026-05-20T01:45:00.602351+00:00