Electronic Structure of the Bond Disproportionated Bismuthate Ag2BiO3

Abstract

We present a comprehensive study on the silver bismuthate Ag2BiO3, synthesized under high-pressure high-temperature conditions, which has been the subject of recent theoretical work on topologically complex electronic states. We present X-ray photoelectron spectroscopy results showing two different bismuth states, and X-ray absorption spectroscopy results on the oxygen K-edge showing holes in the oxygen bands. These results support a bond disproportionated state with holes on the oxygen atoms for Ag2BiO3. We estimate a band gap of 1.25~eV for Ag2BiO3 from optical conductivity measurements, which matches the band gap in density functional calculations of the electronic band structure in the non-symmorphic space group Pnn2, which supports two inequivalent Bi sites. In our band structure calculations the disproportionated Ag2BiO3 is expected to host Weyl nodal chains, one of which is located 0.5~eV below the Fermi level. Furthermore, we highlight similarities between Ag2BiO3 and the well-known disproportionated bismuthate BaBiO3, including breathing phonon modes with similar energy. In both compounds hybridization of Bi-6s and O-2p atomic orbitals is important in shaping the band structure, but in contrast to the Ba-5p in BaBiO3, the Ag-4d bands in Ag2BiO3 extend up to the Fermi level.

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