Effect of Pressure and Oxygen-Isotope Substitution on Density-Wave Transitions in La4Ni3O10

Abstract

Understanding the interplay between magnetism and superconductivity in nickelate systems is a key objective in condensed matter physics. Here, we present a systematic muon-spin rotation/relaxation (μSR) and resistivity study of the trilayer Ruddlesden-Popper nickelate La4Ni3O10 under ambient and applied pressure, combined with oxygen-isotope substitution. At ambient pressure, two incommensurate spin-density-wave (SDW) transitions are identified at TSDW132 K and T80-90 K. Comparison of the internal magnetic fields with dipole-field calculations reveals a magnetic structure consistent with antiferromagnetically coupled SDW order on the outer two Ni layers, with smaller moments on the inner layer. Above T, the moments lie mainly in the ab plane, whereas below this temperature they develop a c-axis component. The internal fields at the muon stopping sites appear abruptly at TSDW, suggesting a first-order-like SDW transition closely linked to the charge-density-wave (CDW) order occurring at the same temperature (TSDW=TCDW). Under pressure, all transition temperatures -- TSDW, T, and TCDW -- are suppressed at a nearly uniform rate of -13 K/GPa. This contrasts with bilayer La3Ni2O7, where pressure enhances the separation between the SDW and CDW transitions. Oxygen-isotope substitution (16O → 18O) shifts TCDW to higher values. The isotope effect on TSDW and T differs markedly: when CDW and SDW are intertwined, a notable isotope effect is observed on TSDW, yielding nearly identical isotope shifts for TCDW and TSDW, whereas no isotope effect is detected at T, where the SDW transition occurs independently of the CDW.

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