Theoretical analysis of band alignment and charge carriers migration in mixed-phase TiO2 systems
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Photocatalysts based on mixtures of rutile and anatase forms of titania usually show a better catalytic performance than each individual component. In order to understand this behavior, several experimental and theoretical approaches have been proposed in the past, looking for an adequate reference frame for aligning energy bands, and arriving sometimes to opposite results. In this work, the theoretical results obtained for the band alignment applying a modified common anion rule for different possibilities of mixed-phase (anatase–rutile) interaction are presented. According to our results, mixed-phase systems involve the transfer of electrons from rutile to anatase and holes from anatase to rutile. This analysis would be applicable to real samples of mixed phase of titania with large particle size. However, for heterogeneous size particulate systems, it is not only necessary to consider the alignment of bands of the bulk system, but also those of the corresponding surfaces. In keeping with the analysis performed, the best mixed systems are those composed by large particles of both polymorphs or by small particles of anatase dissolved in rutile. Our results could explain the disagreement found in the literature regarding the experimental works.
KeywordsMixed-phase titania Band alignment DFT Common anion rule Heterojunction
The authors thank the financial support from the Consejo Nacional de Investigaciones Científicas y Técnicas (CONICET) and the Universidad Nacional del Sur (UNS) (PGI: 24/F068).
- 7.Milnes, A.G., Feucht, D.L.: Heterojunctions and Metal-Semiconductor Junctions. Academic Press, New York (1972)Google Scholar
- 10.Klein, A.: Energy band alignment at interfaces of semiconducting oxides: a review of experimental determination using photoelectron spectroscopy and comparison with theoretical predictions by the electron affinity rule, charge neutrality levels, and the common anion rule. Thin Solid Films 520, 3721–3728 (2012)CrossRefGoogle Scholar
- 30.Bader, R.F.W.: Atoms in Molecules: A Quantum Theory. Oxford University Press, Oxford (1990)Google Scholar