Abstract
Recently, oxynitrides materials such as β-TaON has been using as a photoanode material in the field of photocatalysis and is found to be promising due to its suitable band gap and charge carrier mobility. Computational study of the crystalline β-TaON in the form of primitive unit cell, supercell and its N, Ta, and O terminated surfaces are carried out with the help of periodic density functional theory (DFT). Optical and electronic properties of all these different species are simulated, which predict TaON as the best candidate for photocatalytic water splitting contrast to their Ta2O5 and Ta3N5 counterparts. The calculated bandgap, valence band, and conduction band edge positions predict that β-TaON should be an efficient photoanodic material. The valence band is made up of N 2p orbitals with a minor contribution from O 2p, while the conduction band is made up of Ta 5d. Turning to thin films, the valence band maximum; VBM (−6.4 eV vs. vacuum) and the conduction band minimum; CBM (−3.3 eV vs. vacuum) of (010)-O terminated surface are respectively well below and above the redox potentials of water as required for photocatalysis. Charge carriers have smaller effective masses than in the (001)-N terminated film (VBM −5.8 and CBM −3.7 eV vs. vacuum). However, due to wide band gap (3.0 eV) of (010)-O terminated surface, it cannot absorb visible wavelengths. On the other hand, the (001)-N terminated TaON thin film has a smaller band gap in the visible region (2.1 eV) but the bands are not aligned to the redox potential of water. Possibly a mixed phase material would produce an efficient photoanode for solar water splitting, where one phase performs the oxidation and the other reduction.
Highlights
Solar fuel (H2) is generated by photocatalytic water splitting when sunlight irradiates on a suitable semiconducting material [1,2,3]
Photocatalysts drive the dissociation of water by coupling this to the photo-excitation of electrons [6,7], and an ideal material must have a narrow band gap corresponding to the absorption of visible light and band edge positioned appropriately, so, that the valence band maximum (VBM) is more negative than the redox potential for oxidation of water (−5.7 eV vs. vacuum) and the conduction band minimum (CBM) more positive than the redox potential for reduction of water (−4.5 eV vs. vacuum)
Periodic density functional theory calculations for bulk and potential photoelectrode thin films of β-Tantalum oxynitride (TaON) are carried out considering N, Ta, and O terminations
Summary
Solar fuel (H2) is generated by photocatalytic water splitting when sunlight irradiates on a suitable semiconducting material [1,2,3]. Oxynitrides have recently attracted much attention [9,10,11,12,13,14,15] while transition metal oxide semiconductors are suitable candidates as photocatalysts for storable fuels because of their low cost, nontoxicity, abundance, and high corrosion resistance [16,17,18] They have low efficiencies due to their poor carrier conductivity and generally have large bandgaps [19]. It has been reported that suitable energy of valence and conduction band edges of TaON make it an electrode material for both water oxidation and reduction, and a narrow band gap of ∼2.4 eV allows absorption of visible light [16,27,28].
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