Magnetism of the alternating monolayer-trilayer phase of La3Ni2O7

Abstract

Understanding the magnetic ground state of Ruddlesden-Popper nickelates is crucial, as these materials exhibit superconductivity under high pressure and host competing electronic orders that may play a key role in the pairing mechanism. In this work, we investigate the magnetic properties of the alternating monolayer-trilayer phase of La3Ni2O7 (1313-La3Ni2O7) using muon-spin rotation/relaxation (μSR) under both ambient and hydrostatic pressure conditions. The monolayer-trilayer phase develops incommensurate magnetic order below approximately 150 K, with a mean ordering temperature of TSDW 123 K and a transition width of TSDW 15 K. The abrupt onset of the internal magnetic field indicates a first-order-like transition. Hydrostatic pressure (p) suppresses the magnetic ordering temperature at a rate of dTSDW/d p -3.9 K/GPa, demonstrating a progressive destabilization of the ordered state. By comparison with the bilayer 2222-La3Ni2O7 and the trilayer 3333-La4Ni3O10 systems, and within a unified phenomenological framework, systematic trends are identified linking the pressure dependence of TSDW, the (in)commensurability of the magnetic order, and the character of the magnetic transition. These trends consistently indicate a gradual reduction of electronic correlation strength from the bilayer to the monolayer-trilayer and trilayer nickelates. This hierarchy suggests that the higher superconducting transition temperature observed in the 2222 phase may be closely connected to its more strongly correlated electronic nature. These results position the alternating monolayer-trilayer 1313-La3Ni2O7 as an intermediate member linking the magnetic behavior of the bilayer 2222-La3Ni2O7 and the trilayer 3333-La4Ni3O10 Ruddlesden-Popper compounds.

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