Local Structural Disorder in Metavanadates MV2O6 (M = Zn and Cu) Synthesized by the Deep Eutectic Solvent Route: Photoactive Oxides with Oxygen Vacancies

Metavanadates MV2O6-delta (M = Zn and Cu) are synthesized by using a deep eutectic solvent (DES), a mixture of hydrogen bond donor and acceptor, as a reaction medium. Dissolution of stable binary metal oxides in a DES followed by a heat treatment yields phase-pure vanadates. According to in situ powder X-ray diffraction, ternary phases (alpha-Zn2V2O7 and beta-Cu2-xV2O7, x similar to 0.27) are intermediates in the reaction pathway taken. Identifying a polymorphic phase transformation temperature for CuV2O6 as well as the narrow temperature range between formation and decomposition for both metavanadates allows for tackling the challenge of the synthesis of these materials. The oxygen vacancy introduced by the DES route is accompanied by the formation of reduced V4+ and Cu+ in the oxide matrix, based on X-ray photoelectron spectroscopy. These oxygen vacancies modify the vibrational modes in the corresponding Raman spectra and are also responsible for broad optical absorptions in the 1.8-1.1 eV range. The optical band gaps of the materials are found at 1.8 eV (CuV2O6) and 2.2 eV (ZnV2O6), approximately 0.1-0.3 eV below the values reported in the literature. The reduced band gaps and sub-band gap photon absorption are key features of the oxygen-deficient metavanadates. Surface photovoltage spectroscopy reveals that all the synthesized vanadates are n-type materials with electrons as the majority charge carriers, and photoelectrochemical measurements confirm photoanodic currents for methanol oxidation. These results provide insight into the synthesis and structure-property relationship of the metavanadates for their potential use as photoanodes.

Automated summary

Metavanadates MV2O6-delta (M = Zn and Cu) were synthesized using a deep eutectic solvent (DES) as a reaction medium, resulting in the formation of oxygen-deficient materials with reduced band gaps and enhanced sub-band gap photon absorption. The presence of oxygen vacancies introduced by the DES route significantly altered the structural and optical properties of the oxides. Photoelectrochemical measurements confirmed the potential use of these materials as photoanodes for methanol oxidation, with n-type behavior and electron majority charge carriers identified through surface photovoltage spectroscopy.