Frustrated superconductivity and intrinsic reduction of Tc in trilayer nickelate

Abstract

Identifying the key factors controlling the magnitude of Tc is of critical importance in the pursuit of high-temperature superconductivity. In cuprates, Tc reaches its maximal value in trilayer structure, leading to the belief that interlayer coupling may help promote the pairing. In contrast, for the recently discovered nickelate superconductors under high pressure, the maximum Tc is reduced from about 80 K in the bilayer La3Ni2O7 to 30 K in the trilayer La4Ni3O10. Motivated by this opposite trend, we propose an interlayer pairing scenario for the superconductivity of La4Ni3O10. Our theory reveals intrinsic frustration in the spin-singlet pairing that the inner layer tends to form with both of the two outer layers respectively, leading to strong superconducting fluctuations between layers. This explains the reduction of its maximum Tc compared to that of the bilayer La3Ni2O7. Our findings support a fundamental distinction between multilayer nickelate and cuprate superconductors, and ascribe it to their different (interlayer versus intralayer) pairing mechanisms. Furthermore, our theory predicts extended s-wave gap structures in La4Ni3O10, with varying signs and possible nodes on different Fermi pockets. We also find an intrinsic Josephson coupling with potentially interesting consequences that may be examined in future experiments. Our work reveals the possibility of rich novel physics in multilayer superconductors with interlayer pairing.

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