TiNF and Related Analogues of TiO2: A Combined Experimental and Theoretical Study

Aliovalent anion substitution in inorganic materials brings about marked changes in properties, as exemplified by N,F‐codoped metal oxides. Recently, complete substitution of oxygen in ZnO by N and F was carried out to generate Zn2NF. In view of the important properties of TiO2, we have attempted to...

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Bibliographic Details
Published in:Chemphyschem 2018-12, Vol.19 (24), p.3410-3417
Main Authors: Ayyub, Mohd Monis, Prasad, Suchitra, Lingampalli, Srinivasa Rao, Manjunath, Krishnappa, Waghmare, Umesh V., Rao, C. N. R.
Format: Article
Language:English
Subjects:
aliovalent anions
Anatase
band-gap tuning
Crystal structure
Electronic properties
Electronic structure
Energy gap
first-principles calculations
Inorganic materials
Lattice parameters
Optical properties
Phase transitions
Rutile
Substitution reactions
Titanium dioxide
Titanium oxides
Zinc oxide
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Summary:Aliovalent anion substitution in inorganic materials brings about marked changes in properties, as exemplified by N,F‐codoped metal oxides. Recently, complete substitution of oxygen in ZnO by N and F was carried out to generate Zn2NF. In view of the important properties of TiO2, we have attempted to prepare TiNF by employing an entirely new procedure involving the reaction of TiN with TiF4. While the reaction at low temperature (450 °C) yields TiNF in the anatase phase, reaction at a higher temperature (600 °C) yields TiNF in the rutile phase. This is interesting since the anatase phase of TiO2 also transforms to the rutile phase on heating. The lattice parameters of TiNF are close to those of the parent oxide. Partial substitution of oxygen in TiO2 by N and F reduces the band gap, but complete substitution increases the value comparable to that of the oxide. We have examined properties of N,F‐codoped TiO2, and more interestingly N,F‐codoped Ti3O5, both with lower band gaps than the parent oxides. A detailed first‐principles calculations has been carried out on structural and electronic properties of N,F−TiO2 and the TiNF phases. This has enabled us to understand the effects of N,F substitution in TiO2 in terms of the crystal structure, electronic structure and optical properties. Oxygen is substituted by nitrogen and fluorine in TiO2. Experimental and theoretical studies are carried out to study the properties of the materials.
ISSN:1439-4235
1439-7641
DOI:10.1002/cphc.201800778