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Electronic structure of the kagome staircase compounds Ni3V2O8 and Co3V2O8

The electronic structure of the kagome staircase compounds, Ni3V2O8 and Co3V2O8, has been investigated using soft x-ray absorption, soft x-ray emission, and resonant inelastic x-ray scattering (RIXS). Comparison between the two compounds, and with first principles band structure calculations and crystal-field multiplet models, provide unique insight into the electronic structure of the two materials. Whereas the location of the narrow (Ni,Co) d bands is predicted to be close to EF, we experimentally find they lie deeper in the occupied O 2p and unoccupied V 3d manifolds, and determine their energy via measured charge-transfer excitations. Additionally, we find evidence for a dd excitation at 1.5 eV in Ni3V2O8, suggesting the V d states may be weakly occupied in this compound, contrary to Co3V2O8. Good agreement is found between the crystal-field dd excitations observed in the experiment and predicted by atomic multiplet theory.

preprint2013arXivOpen access
J. LaverockB. ChenA. R. H. PrestonK. E. SmithN. R. WilsonG. BalakrishnanP. -A. GlansJ. -H. Guo
cond-mat.str-el
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J. LaverockB. ChenA. R. H. PrestonK. E. SmithN. R. WilsonG. BalakrishnanP. -A. GlansJ. -H. Guo

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