Pressure-Invariant Isotope Effect as Evidence for Electronically Driven Intertwined Order in Pr4Ni3O10

Abstract

We report muon-spin rotation measurements of the pressure dependence of the oxygen-isotope (16O/18O) effect on the spin-density wave (SDW) transition in the trilayer Ruddlesden-Popper nickelate Pr4Ni3O10. At ambient pressure, the SDW transition shows a finite isotope shift, with 16T SDW=158.04(5) K and 18T SDW=159.81(6) K. Under hydrostatic pressure, T SDW decreases linearly at nearly identical rates for the two isotope compositions, d\,16T SDW/ dp=-4.93(5) K/GPa and d\,18T SDW/ dp=-4.90(7) K/GPa, such that the isotope shift remains essentially unchanged under compression. The absence of pressure enhancement of the isotope effect points to a predominantly electronic origin of the SDW transition and is consistent with recent inelastic x-ray scattering results, suggesting a new regime of intertwined order in trilayer RP nickelates, which is stabilized by strong spin interactions.

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