Reaction Intermediates in the Photoreduction of Oxygen Molecules at the (101) TiO<sub>2</sub> (Anatase) Surface

Mattioli, Giuseppe; Filippone, F.; Bonapasta, A. Amore

doi:10.1021/ja062145x

Cited by 82 publications

(101 citation statements)

References 37 publications

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“…Prior to the adsorption of O 2 and H 2 O molecules on the Zn 3 P 2 surfaces, the reference energies, bond length (d), and 37 and 1555 cm À1 , 38 as well as with other DFT results. [39][40][41] The d(O-H) and a(HOH) angles of water are calculated to be 0.972 Å and 104.71 respectively, and the calculated asymmetric and symmetric stretching vibrational frequencies are predicted at 3713 and 3623 cm À1 , all of which are in good agreement with experimental values. 42 To characterize the extent of oxidation or reduction of the surface species due to the adsorption of O 2 and H 2 O molecules, Bader charge analysis 44 was performed on all stable adsorbate-surface systems and the results were compared to those of the naked surface counterparts.…”

Section: Computational Detailssupporting

confidence: 63%

Unravelling the early oxidation mechanism of zinc phosphide (Zn₃P₂) surfaces by adsorbed oxygen and water: a first-principles DFT-D3 investigation

Dzade

2020

Phys. Chem. Chem. Phys.

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Section: Computational Detailssupporting

confidence: 63%

Unravelling the early oxidation mechanism of zinc phosphide (Zn₃P₂) surfaces by adsorbed oxygen and water: a first-principles DFT-D3 investigation

Dzade

2020

Phys. Chem. Chem. Phys.

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“…X-ray diffraction (XRD) was used to characterize the asprepared titania sample (designated simply as TiO 2 ) and the treated samples TiO 2ox and TiO 2vac . The XRD pattern of each sample ( Figure 1) includes strong, sharp peaks at 25,38,48,54,55,63,69,70, and 758, matching that of anatase (JCPDS No. .…”

Section: Resultsmentioning

confidence: 99%

Probing Defect Sites on TiO₂ with [Re₃(CO)₁₂H₃]: Spectroscopic Characterization of the Surface Species

Suriye

Lobo‐Lapidus²,

Yeagle

et al. 2008

Chemistry A European J

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Samples of the anatase phase of titania were treated under vacuum to create Ti(3+) surface-defect sites and surface O(-) and O(2) (-) species (indicated by electron paramagnetic resonance (EPR) spectra), accompanied by the disappearance of bridging surface OH groups and the formation of terminal Ti(3+)-OH groups (indicated by IR spectra). EPR spectra showed that the probe molecule [Re(3)(CO)(12)H(3)] reacted preferentially with the Ti(3+) sites, forming Ti(4+) sites with OH groups as the [Re(3)(CO)(12)H(3)] was adsorbed. Extended X-ray absorption fine structure (EXAFS) spectra showed that these clusters were deprotonated upon adsorption, with the triangular metal frame remaining intact; EPR spectra demonstrated the simultaneous removal of surface O(-) and O(2) (-) species. The data determined by the three complementary techniques form the basis of a schematic representation of the surface chemistry. According to this picture, during evacuation at 773 K, defect sites are formed on hydroxylated titania as a bridging OH group is removed, forming two neighboring Ti(3+) sites, or, when a Ti(4+)-O bond is cleaved, forming a Ti(3+) site and an O(-) species, with the Ti(4+)-OH group being converted into a Ti(3+)-OH group. When the probe molecule [Re(3)(CO)(12)H(3)] is adsorbed on a titania surface with Ti(3+) defect sites, it reacts preferentially with these sites, becoming deprotonated, removing most of the oxygen radicals, and healing the defect sites.

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“…Despite these limitations, TiO 2 is nevertheless widely used as a photocatalyst where efficiency and rapid reactions are not critical, such as in self-cleaning and antibacterial surfaces. [15][16][17] The rate of electron transfer to O 2 that is in solution and not adsorbed to the TiO 2 surface is insignificant, and thus the rate of oxygen reduction by photoexcited electrons on the perfect (101) anatase surface is slow. , which subsequently accepts two protons to form H 2 O 2 (hydrogen peroxide) that readily oxidizes the OP.…”

Section: Introductionmentioning

confidence: 99%

Increasing the Photocatalytic Activity of Anatase TiO₂ through B, C, and N Doping

et al. 2014

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We utilized density functional theory (DFT) to systematically investigate the ability of B, C and N interstitial and O substitutional surface and near-surface dopants in TiO 2 to facilitate O 2 reduction and adsorption. Periodic boundary condition calculations based on the PBE+U DFT functional show that dopants that create filled band gap states with energies higher than that of the near surface O 2 π z * molecular orbital enable O 2 adsorption and reduction. Sites that create unoccupied band gap states with energies below that of the O 2 π z * orbital reduce TiO 2 's reduction ability as these states result in photoexcited electrons with insufficient reduction potential to reduce O 2 . B dopants in interstitial and relaxed substitutional sites, whose gap states lie > 1.5 eV above the valence band maximum (VBM) and hence above O 2 's π z * level, facilitate the reduction of O 2 to the peroxide state with adsorption energies on TiO 2 of -1.22 to -2.77 eV.However, N dopants, whose gap states lie less than ~1 eV above the VBM impede O 2 adsorption and reduction; O 2 on N doped (101) anatase relaxes away from the surface. Interstitial and substitutional N dopants require two photoexcited electrons to enable O 2 adsorption. C doping, which introduces gap states between those introduced by N and B, aids O 2 adsorption as a peroxide for interstitial doping, although substitutional C does not facilitate O 2 adsorption. Dopants for enhancing the photocatalytic reduction of O 2 in order of predicted effectiveness are interstitial B, relaxed substitutional B, and interstitial C. In contrast, substitutional C, and interstitial and substitutional N hinder O 2 reduction despite increasing visible light absorption.Dopants within the surface layer likely deactivate quickly due to the high exothermicity of O 2 reacting with them to form BO 2 , CO 2 , and NO 2 .

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Reaction Intermediates in the Photoreduction of Oxygen Molecules at the (101) TiO₂ (Anatase) Surface

Cited by 82 publications

References 37 publications

Unravelling the early oxidation mechanism of zinc phosphide (Zn₃P₂) surfaces by adsorbed oxygen and water: a first-principles DFT-D3 investigation

Unravelling the early oxidation mechanism of zinc phosphide (Zn₃P₂) surfaces by adsorbed oxygen and water: a first-principles DFT-D3 investigation

Probing Defect Sites on TiO₂ with [Re₃(CO)₁₂H₃]: Spectroscopic Characterization of the Surface Species

Increasing the Photocatalytic Activity of Anatase TiO₂ through B, C, and N Doping

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Reaction Intermediates in the Photoreduction of Oxygen Molecules at the (101) TiO2 (Anatase) Surface

Cited by 82 publications

References 37 publications

Unravelling the early oxidation mechanism of zinc phosphide (Zn3P2) surfaces by adsorbed oxygen and water: a first-principles DFT-D3 investigation

Unravelling the early oxidation mechanism of zinc phosphide (Zn3P2) surfaces by adsorbed oxygen and water: a first-principles DFT-D3 investigation

Probing Defect Sites on TiO2 with [Re3(CO)12H3]: Spectroscopic Characterization of the Surface Species

Increasing the Photocatalytic Activity of Anatase TiO2 through B, C, and N Doping

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Reaction Intermediates in the Photoreduction of Oxygen Molecules at the (101) TiO₂ (Anatase) Surface

Unravelling the early oxidation mechanism of zinc phosphide (Zn₃P₂) surfaces by adsorbed oxygen and water: a first-principles DFT-D3 investigation

Unravelling the early oxidation mechanism of zinc phosphide (Zn₃P₂) surfaces by adsorbed oxygen and water: a first-principles DFT-D3 investigation

Probing Defect Sites on TiO₂ with [Re₃(CO)₁₂H₃]: Spectroscopic Characterization of the Surface Species

Increasing the Photocatalytic Activity of Anatase TiO₂ through B, C, and N Doping