Identical Suppression of Spin and Charge Density Wave Transitions in La4Ni3O10 by Pressure

Understanding the interplay between magnetism and superconductivity in nickelate systems is a key focus of condensed matter research. Microscopic insights into magnetism, which emerges near superconductivity, require a synergistic approach that combines complementary techniques with controlled parameter tuning. In this paper, we present a systematic investigation of the three-layer Ruddlesden-Popper (RP) nickelate La$_4$Ni$_3$O$_{10}$ using muon-spin rotation/relaxation ($\mu$SR), neutron powder diffraction (NPD), resistivity, and specific heat measurements. At ambient pressure, two incommensurate spin density wave (SDW) transitions were identified at $T_{\rm SDW} \simeq 132$~K and $T^\ast \simeq 90$~K. NPD experiments revealed that the magnetic wave vector $(0, 0.574, 0)$ remains unchanged below 130~K, indicating that the transition at $T^\ast$ corresponds to a reorientation of the Ni magnetic moments within a similar magnetic structure. Comparison of the observed internal magnetic fields with dipole-field calculations reveals a magnetic structure consistent with an antiferromagnetically coupled SDW on the outer two Ni layers, with smaller moments on the inner Ni layer. The internal fields at muon stopping sites appeared abruptly at $T_{\rm SDW}$, suggesting a first-order-like nature of the SDW transition, which is closely linked to the charge density wave (CDW) order occurring at the same temperature ($T_{\rm SDW} = T_{\rm CDW}$). Under applied pressure, all transition temperatures, including $T_{\rm SDW}$, $T^\ast$, and $T_{\rm CDW}$, were suppressed at a nearly uniform rate of $\simeq -13$~K/GPa. This behavior contrasts with the double-layer RP nickelate La$_3$Ni$_2$O$_7$, where pressure enhances the separation of the density wave transitions.