Electronic Nematicity Revealed by Polarized Ultrafast Spectroscopy in Bilayer La3Ni2O7

Abstract

We report a polarized ultrafast pump-probe study of the normal-state electronic dynamics in bilayer La3Ni2O7 and trilayer La4Ni3O10 single crystals at ambient pressure. While both nickelates exhibit density-wave (DW) transitions accompanied by the opening of a quasiparticle relaxation bottleneck, their electronic responses display strikingly different symmetry properties. La4Ni3O10 maintains an isotropic optical response across the entire temperature range. In contrast, La3Ni2O7 exhibits a pronounced twofold (C2) anisotropy in its lowtemperature electronic dynamics. This electronic nematicity, evident in both the relaxation dynamics and the polarization-dependent effective bottleneck energy scales, is strongly modified below 115 K, suggesting coupling or competition with a secondary DW-like instability reported by complementary probes. The presence of macroscopic electronic anisotropy in the bilayer system, and its absence in the trilayer system, suggests a possible relation between electronic nematic correlations and the superconducting normal state in a3Ni2O7 that deserves further exploration.