A. M. Czoska scite author profile

Fluorine-doped titanium dioxide was prepared via sol−gel synthesis and subsequent calcination in air. The presence of fluorine in the lattice induces the formation of reduced Ti3+ centers that localize the extra electron needed for charge compensation and are observed by electron paramagnetic resonance. Density functional theory calculations using hybrid functionals are in full agreement with such description. The extra electron is highly localized in a 3d orbital of titanium and lies a few tenths of an electron volt below the bottom of the conduction band. The preparation via sol−gel synthesis using aqueous solutions of fluorides also causes the formation of surface F− ions that substitute surface hydroxyl groups (OH−) without generating reduced centers.

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Density Functional Theory and Electron Paramagnetic Resonance Study on the Effect of N−F Codoping of TiO₂

Valentin¹,

Finazzi²,

Pacchioni³

et al. 2008

Chem. Mater.

191

181

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Recent experiments have indicated that titanium dioxide (TiO2) codoped with nitrogen and fluorine may show enhanced photocatalytic activity in the visible region with respect to TiO2 doped only with nitrogen. Prompted by these findings, we have investigated N−F codoped TiO2 through a combined theoretical and experimental study. Density functional theory (DFT) calculations have been carried out both within the generalized gradient approximation (GGA) and using hybrid functionals to accurately describe the electronic structure; substitutional as well as interstitial locations of nitrogen in the TiO2 lattice were considered. From these calculations we infer that N−F codoping reduces the energy cost of doping and also the amount of defects (number of oxygen vacancies) in the lattice, as a consequence of the charge compensation between the nitrogen (p-dopant) and the fluorine (n-dopant) impurities. The UV−visible spectra of the sol−gel prepared TiO2 powders confirm the synergistic effect of N−F codoping: more impurities are introduced in the lattice with an increased optical absorption in the visible. EPR spectroscopy measurements on the codoped samples identify two paramagnetic species which are associated to bulk N impurities (Nb •) and Ti3+ ions. Preliminary photocatalytic tests also indicate an enhanced activity under vis-light irradiation toward degradation of methylene blue for the codoped system with respect to N-doped TiO2.

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The nitrogen–boron paramagnetic center in visible light sensitized N–B co-doped TiO₂. Experimental and theoretical characterization

Czoska

Livraghi

Paganini

et al. 2011

Phys. Chem. Chem. Phys.

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Nitrogen boron co-doped TiO(2) prepared via sol-gel synthesis and active under visible light, contains two types of paramagnetic extrinsic defects, both exhibiting a well resolved EPR spectrum. The first center is the well characterized [N(i)O]˙ species (i = interstitial) also present in N-doped TiO(2), while the second one involves both N and B. This latter center (labeled [NOB]˙) exhibits well resolved EPR spectra obtained using either (14)N or (15)N which show a high spin density in a N 2p orbital. The structure of the [NOB]˙ species is different from that previously proposed in the literature and is actually based on the presence of interstitial N and B atoms both bound to the same lattice oxygen ion. The interstitial B is also linked to two other lattice oxygen ions reproducing the trigonal planar structure typical of boron compounds. The energy level of the [NOB]˙ center lies near the edge of the valence band of TiO(2) and, as such, does not contribute to the visible light absorption. However, [NOB]˙ can easily trap one electron generating the [NOB](-) diamagnetic center which introduces a gap state at about 0.4 eV above the top of the valence band. This latter species can contribute to the visible light activity.

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Nitrogen-doped and nitrogen–fluorine-codoped titanium dioxide. Nature and concentration of the photoactive species and their role in determining the photocatalytic activity under visible light

Livraghi

Elghniji

Czoska

et al. 2009

Journal of Photochemistry and Photobiology A: Chemistry

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A. M. Czoska

The Nature of Defects in Fluorine-Doped TiO₂

Density Functional Theory and Electron Paramagnetic Resonance Study on the Effect of N−F Codoping of TiO₂

The nitrogen–boron paramagnetic center in visible light sensitized N–B co-doped TiO₂. Experimental and theoretical characterization

Nitrogen-doped and nitrogen–fluorine-codoped titanium dioxide. Nature and concentration of the photoactive species and their role in determining the photocatalytic activity under visible light

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About

A. M. Czoska

The Nature of Defects in Fluorine-Doped TiO2

Density Functional Theory and Electron Paramagnetic Resonance Study on the Effect of N−F Codoping of TiO2

The nitrogen–boron paramagnetic center in visible light sensitized N–B co-doped TiO2. Experimental and theoretical characterization

Nitrogen-doped and nitrogen–fluorine-codoped titanium dioxide. Nature and concentration of the photoactive species and their role in determining the photocatalytic activity under visible light

Contact Info

Product

Resources

About

The Nature of Defects in Fluorine-Doped TiO₂

Density Functional Theory and Electron Paramagnetic Resonance Study on the Effect of N−F Codoping of TiO₂

The nitrogen–boron paramagnetic center in visible light sensitized N–B co-doped TiO₂. Experimental and theoretical characterization