Trigonal Distortion Driven Ground States in VX3 (X = Br and I)

Abstract

Transition-metal halides VX3 (X = Br and I) have emerged as promising candidates for two dimensional spintronic and quantum applications due to their layer-dependent magnetism and tunable electronic states. However, experimental insights into their ground state electronic structures remain limited. Here, we present a comprehensive investigation of VX3 using high resolution resonant inelastic x-ray scattering (RIXS) combined with ligand field multiplet calculations. The RIXS spectra reveal distinct dd and charge-transfer excitations, allowing precise determination of electronic structure parameters, including the crystal field splitting, trigonal distortion, and Racah parameters. The determined parameters showed clear variation, indicating an increase in covalency from Br to I. The trigonal distortion parameters ΔD3d were determined to be -0.096 eV in VBr3 and 0.07 eV in VI3, indicating a sign opposition between the two compounds, reflecting good agreement with experimental RIXS data. Cluster model calculations yield a high-spin V3+ (S = 1) configuration, with an e'2g ground state in VBr3 and an e'1ga11g ground state in VI3, consistent with trigonal elongation and compression, respectively. Our findings provide the most complete experimental determination of the low energy electronic structure in VX3, offering valuable insights for designing 2D magnetic and spintronic materials based on vanadium halides.