Enhancement of Photocatalytic Activity of Mesporous TiO<sub>2</sub> Powders by Hydrothermal Surface Fluorination Treatment

Wang, Yuanyuan; Wang, Wenguang; Su, Bao‐Lian

doi:10.1021/jp900136q

Cited by 594 publications

(410 citation statements)

References 73 publications

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“…The as-prepared anatase TiO 2 presented a 140.1 m 2 /g BET surface area, 5.44 nm pore diameter and 0.19 cm 3 /g pore volume. The surface fluorination resulted in a sharp drop in the BET surface area but a sharp increase in the pore size and pore volume of F-TiO 2 due to growth of TiO 2 crystallites [23,39]. In contrast, the defluorination process did not induce much difference in BET surface area, pore diameter and pore volume of samples.…”

Section: Bet Surface Area and Pore Size Distributionmentioning

confidence: 89%

“…The fluoride peak at binding energy 684.5 eV (F 1s) only appears in the F-TiO 2 sample, indicating the formation of surface fluoride ( Ti-F) by a ligand exchange reaction between F − and the surface hydroxyl group on the TiO 2 surface [40][41][42][43][44]. No peak for F − ions in the lattice at 688.5 eV was observed in the spectra, because the hydrothermal process could prevent the substitution of F − for O 2− in the lattice of TiO 2 [21,39,40,45]. The fluoride peak in the D-TiO 2 almost disappeared after defluorination, indicating that the surface fluorine atoms were removed by NaOH washing for 10 h [46].…”

Section: Xps Analysismentioning

confidence: 99%

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Photocatalytic oxidation of gaseous ammonia over fluorinated TiO2 with exposed (001) facets

et al. 2014

Applied Catalysis B: Environmental

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a b s t r a c tA surface-fluorinated TiO 2 (F-TiO 2 ) catalyst was synthesized by a hydrothermal method using hydrofluoric acid (HF) solution as a capping agent, and defluorinated TiO 2 (D-TiO 2 ) was next obtained by washing the F-TiO 2 with NaOH solution. The as-prepared catalysts were tested for the photocatalytic oxidation (PCO) of gaseous NH 3 under UV light. The F-TiO 2 catalyst exhibited remarkable activity for NH 3 removal, about twice as high as that of the commercial catalyst P25. In contrast, D-TiO 2 showed an obvious decrease in PCO activity. The catalysts were characterized by X-ray diffractometry (XRD), Brunauer-Emmett-Teller (BET) adsorption analysis, High-resolution Transmission electron microscopy (HR-TEM), and X-ray photoelectron spectroscopy (XPS). The results showed that the surface fluorination process formed the surface Ti-F group and also increased the percentage of reactive (0 0 1) facets to about 50%; the surface defluorination removed the fluorine (F) element from the F-TiO 2 surface but showed no influence on the percentage of reactive (0 0 1) facets. By comparing the specific activities of the catalysts, we found that both the active (0 0 1) facets and the surface Ti-F group contributed to the improvement of the PCO activity, while the surface Ti-F group plays the dominant role. The Ti-F group could retard the recombination of photogenerated electrons and holes, which is possibly the major reason for the excellent activity of the F-TiO 2 catalyst.

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Section: Bet Surface Area and Pore Size Distributionmentioning

confidence: 89%

Section: Xps Analysismentioning

confidence: 99%

Photocatalytic oxidation of gaseous ammonia over fluorinated TiO2 with exposed (001) facets

et al. 2014

Applied Catalysis B: Environmental

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“…The enhancement in the H 2 evolution in presence of graphene in TiO 2 could be due to excellent electron accepting and transferring capability, and the capacity to restrain the recombination of the photo-excited electrons and holes effectively. It has been reported that the two-dimensional π-conjugation structure of graphene sheets facilitates the transfer of photo-induced electrons and can act as an excellent electron acceptor [57,58]. A further increase in graphene content leads to a reduction of the photo-catalytic activity.…”

Section: Photo-catalytic Hydrogen Evolution From Plasmonic Active Phomentioning

confidence: 99%

Graphene supported plasmonic photocatalyst for hydrogen evolution in photocatalytic water splitting

et al. 2014

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It is well known that the noble metal nanoparticles show active absorption in the visible region because of the existence of the unique feature known as surface plasmon resonance (SPR). Here we report the effect of plasmonic Au nanoparticles on the enhancement of the renewable hydrogen (H2) evolution through photocatalytic water splitting. The plasmonic Au/graphene/TiO2 photocatalyst was synthesized in two steps: first the graphene/TiO2 nanocomposites were developed by the hydrothermal decomposition process; then the Au was loaded by photodeposition. The plasmonic Au and the graphene as co-catalyst effectively prolong the recombination of the photogenerated charges. This plasmonic photocatalyst displayed enhanced photocatalytic H2 evolution for water splitting in the presence of methanol as a sacrificial reagent. The H2 evolution rate from the Au/graphene co-catalyst was about 9 times higher than that of a pure graphene catalyst. The optimal graphene content was found to be 1.0 wt %, giving a H2 evolution of 1.34 mmol (i.e., 26 μmolh−1), which exceeded the value of 0.56 mmol (i.e., 112 μmolh−1) observed in pure TiO2. This high photocatalytic H2 evolution activity results from the deposition of TiO2 on graphene sheets, which act as an electron acceptors to efficiently separate the photogenerated charge carriers. However, the Au loading enhanced the H2 evolution dramatically and achieved a maximum value of 12 mmol (i.e., 2.4 mmolh−1) with optimal loading of 2.0 wt% Au on graphene/TiO2 composites. The enhancement of H2 evolution in the presence of Au results from the SPR effect induced by visible light irradiation, which boosts the energy intensity of the trapped electron as well as active sites for photocatalytic activity.

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“…Peaks at 3400, 2930, 2850 cm −1 are attributed to the Ti-OH bond [39]. The TiO 2−x N x sample shows additional peaks at 1450, 1160 cm −1 attributed to nitrogen atom in the TiO 2 matrix [40]. The peak at 600 cm −1 can be assigned to the absorption bands of Ti-O and O-Ti-O.…”

Section: Ftir Analysismentioning

confidence: 99%

“…The practical applications of TiO 2 have been suppressed by the low quantum yield that arises from the rapid recombination of photo-induced charge carriers and the other drawback is the poor solar absorption efficiency that is determined by its band gap. It was found that doping with nonmetals (e.g., boron [4], carbon [5], nitrogen [6] and fluorine [7]), especially nitrogen can successfully modify the electronic structure of TiO 2 , extending the photoresponse of TiO 2 to the visible light region. Many studies have been reported that loading of noble metals (e.g., Pt, Au, or Ag) on the surface of TiO 2 can effectively hinder the recombination and promote the transfer of photo-induced electrons to these metal deposits [8][9][10][11][12].…”

Section: Introductionmentioning

confidence: 99%

Synergistic effect of Ag deposition and nitrogen doping in TiO2 for the degradation of phenol under solar irradiation in presence of electron acceptor

Devi¹,

Nagaraj²,

Rajashekhar³

2012

Chemical Engineering Journal

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a b s t r a c tAg deposited nitrogen doped TiO 2 (Ag-TiO 2−x N x ) was prepared using sol gel titania by grinding it with stoichiometric amount of Urea as nitrogen source followed by the photoreduction of Ag + to Ag 0 . These samples were characterized by powder X-ray diffraction (PXRD), UV-visible absorption spectroscopy, Fourier transformed infrared spectroscopy (FTIR), photoluminescence (PL) and scanning electron microscope (SEM). PL analysis of the samples indicated that the electron-hole recombination has been effectively inhibited after the Ag deposition on TiO 2 and TiO 2−x N x . Ag-TiO 2−x N x exhibits much higher visible-light photocatalytic activity when compared with N-doped or pristine TiO 2 . The catalysts along with the oxidants can accelerate electron transfer process and inhibit the fast electron-hole recombination. The observed high process efficiency (˚) of Ag-TiO 2−x N x particles compared to TiO 2−x N x and pure TiO 2 photocatalyst can be accounted to the synergistic effect of Ag loading along with N doping. Strongly interacting electron accepting species such as hydrogen peroxide and ammonium persulphate chemisorbed at the photocatalyst surface are said to act like surface states enabling inelastic transfer of electrons from the conduction band to the oxidizing species. The electronic states of different energies within the band gap have a major role in enhancing the efficiency.

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Enhancement of Photocatalytic Activity of Mesporous TiO₂ Powders by Hydrothermal Surface Fluorination Treatment

Cited by 594 publications

References 73 publications

Photocatalytic oxidation of gaseous ammonia over fluorinated TiO2 with exposed (001) facets

Photocatalytic oxidation of gaseous ammonia over fluorinated TiO2 with exposed (001) facets

Graphene supported plasmonic photocatalyst for hydrogen evolution in photocatalytic water splitting

Synergistic effect of Ag deposition and nitrogen doping in TiO2 for the degradation of phenol under solar irradiation in presence of electron acceptor

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Enhancement of Photocatalytic Activity of Mesporous TiO2 Powders by Hydrothermal Surface Fluorination Treatment

Cited by 594 publications

References 73 publications

Photocatalytic oxidation of gaseous ammonia over fluorinated TiO2 with exposed (001) facets

Photocatalytic oxidation of gaseous ammonia over fluorinated TiO2 with exposed (001) facets

Graphene supported plasmonic photocatalyst for hydrogen evolution in photocatalytic water splitting

Synergistic effect of Ag deposition and nitrogen doping in TiO2 for the degradation of phenol under solar irradiation in presence of electron acceptor

Contact Info

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Enhancement of Photocatalytic Activity of Mesporous TiO₂ Powders by Hydrothermal Surface Fluorination Treatment