Localization of Conduction Band Electrons in Polycrystalline Ti02 Studied by ESR

Serwicka, Ewa M.; Schlierkamp, M.; Schindler, R. N.

doi:10.1515/zna-1981-0305

Cited by 77 publications

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“…ratio 3:1) measured in the dark at room temperature (RT) and at 100 K. In the EPR spectra of pristine g-C3N4, only a nearly isotropic signal at g = 2.003 (*) was detected (Figure 1), often observed in the EPR spectra of graphitic carbon nitride and attributed to the conduction electrons in the localized π-states of g-C3N4 [30]. An analogous EPR signal found in the TiO2 matrix upon high-temperature treatment was assigned to the medium-polarized conduction electrons or oxygen vacancies [31,32]. Consequently, these electron excess centers may be simultaneously generated during the synthesis of g-C3N4/TiO2 photocatalysts at 550 °C ( Figure 1).…”

Section: Resultsmentioning

confidence: 90%

EPR Investigations of G-C3N4/TiO2 Nanocomposites

et al. 2018

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Abstract:The g-C 3 N 4 /TiO 2 nanopowders prepared by the annealing of melamine and TiO 2 P25 at 550 • C were investigated under dark and upon UV or visible-light photoactivation using X-and Q-band electron paramagnetic resonance (EPR) spectroscopy. The EPR spectra of powders monitored at room temperature and 100 K showed the impact of the initial loading ratio of melamine/TiO 2 on the character of paramagnetic centers observed. For the photocatalysts synthesized using a lower titania content, the paramagnetic signals characteristic for the g-C 3 N 4 /TiO 2 nanocomposites were already found before exposure. The samples annealed using the higher TiO 2 loading revealed the photoinduced generation of paramagnetic nitrogen bulk centers (g-tensor components g 1 = 2.005, g 2 = 2.004, g 3 = 2.003 and hyperfine couplings from the nitrogen A 1 = 0.23 mT, A 2 = 0.44 mT, A 3 = 3.23 mT) typical for N-doped TiO 2 . The ability of photocatalysts to generate reactive oxygen species (ROS) upon in situ UV or visible-light photoexcitation was tested in water or dimethyl sulfoxide by EPR spin trapping using 5,5-dimethyl 1-pyrroline N-oxide. The results obtained reflect the differences in photocatalyst nanostructures caused by the differing initial ratio of melamine/TiO 2 ; the photocatalyst prepared by the high-temperature treatment of melamine/TiO 2 wt. ratio of 1:3 revealed an adequate photoactivity in both spectral regions.

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Section: Resultsmentioning

confidence: 90%

EPR Investigations of G-C3N4/TiO2 Nanocomposites

et al. 2018

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“…* signals with g av % 1.90 attributed to the 1) the unionised deep donor levels, 2) the singly ionised oxygen vacancy, 3) shallow defects; [87,97] * signals with g av (or g iso ) % 1.98 assigned to Sn 3 + ions; [98,99] * isotropic signal with g % g e (2.0023) gives no explanation for SnO 2 . This signal is usually observed on n-type semiconducting oxides; its interpretation is not clear and very controversial: phrases such as "medium polarised electrons", [100] "conduction electrons localised close to adsorbed surface acceptor-like species" [101] are used;…”

Section: Temperature Programmed Desorptionmentioning

confidence: 99%

Interplay between O₂ and SnO₂: Oxygen Ionosorption and Spectroscopic Evidence for Adsorbed Oxygen

2006

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Tin dioxide is the most commonly used material in commercial gas sensors based on semiconducting metal oxides. Despite intensive efforts, the mechanism responsible for gas-sensing effects on SnO(2) is not fully understood. The key step is the understanding of the electronic response of SnO(2) in the presence of background oxygen. For a long time, oxygen interaction with SnO(2) has been treated within the framework of the "ionosorption theory". The adsorbed oxygen species have been regarded as free oxygen ions electrostatically stabilized on the surface (with no local chemical bond formation). A contradiction, however, arises when connecting this scenario to spectroscopic findings. Despite trying for a long time, there has not been any convincing spectroscopic evidence for "ionosorbed" oxygen species. Neither superoxide ions O(2)(-), nor charged atomic oxygen O,(-) nor peroxide ions O(2)(2-) have been observed on SnO(2) under the real working conditions of sensors. Moreover, several findings show that the superoxide ion does not undergo transformations into charged atomic oxygen at the surface, and represents a dead-end form of low-temperature oxygen adsorption on reduced metal oxide.

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“…It is often is assumed that photoexcited electrons in TiO 2 are trapped on Ti IV sites or oxygen vacancies V o , and it is believed that molecular oxygen is adsorbed on the same sites. 2,40,42 By means of LT-ESR, we investigated the presence of V o in undoped TiO 2 and D-TKP 102-A powders (Figure 10). A signal with g ) 2.0030 was found for the powder D-TKP-102-A.…”

Section: -33mentioning

confidence: 99%

Synthesis, Characterization, and Photocatalytic Activities of Nanoparticulate N, S-Codoped TiO₂ Having Different Surface-to-Volume Ratios

et al. 2010

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An efficient, visible light active, N, S-codoped TiO 2 -based photocatalyst was prepared by reacting thiourea with nanoparticulate anatase TiO 2 . Commercial anatase powders were manually ground with thiourea and annealed at 400°C in two crucibles with different surface-to-volume ratios (S/V ) 20 and 1.5) to prepare two N, S-codoped TiO 2 materials. The differentiated aeration conditions during the catalyst annealing on the crucibles allowed for different amounts of O 2 to reach the catalyst surface. The first material, with S/V ) 20, herein referred to as D-TKP 102-A, was clear beige colored. The second material, with S/V ) 1.5, herein referred to as D-TKP 102-B, was darker and revealed a markedly lower efficiency in Escherichia coli inactivation. The D-TKP 102-A powder presented visible light absorption due to the nitrogen (N) and sulfur (S) doping. X-ray photoelectron spectroscopy signals for this catalyst were observed for N 1s peaks at binding energies of 399.2 and 400.7 eV due to interstitial N-doping or Ti-O-N species. The S 2p were due to SO 4 -2 signals with BE >168 eV and signals at 162.8 and 167.2 eV due to anionic and cationic S-doping, respectively. By fast kinetic spectroscopy, the decay of the electron induced by pulsed light at λ ) 450 nm (∼8 ns/laser pulse) was followed for the D-TKP 102-A catalyst. Undoped D-TKP 102 catalyst did not promote the electron in the visible range, and consequently no signal decay could be observed in the latter case. Low-temperature electron spin resonance measurements at 8 K provided evidence for electrons trapped in shallow traps, such as oxygen vacancies, V o , induced by N, S doped on D-TKP 102-A. The ESR measurements implementing the reactive scavenging with singlet oxygen scavenger, TMP-OH, revealed the production of singlet oxygen ( 1 O 2 ).

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Localization of Conduction Band Electrons in Polycrystalline Ti02 Studied by ESR

Cited by 77 publications

References 0 publications

EPR Investigations of G-C3N4/TiO2 Nanocomposites

EPR Investigations of G-C3N4/TiO2 Nanocomposites

Interplay between O₂ and SnO₂: Oxygen Ionosorption and Spectroscopic Evidence for Adsorbed Oxygen

Synthesis, Characterization, and Photocatalytic Activities of Nanoparticulate N, S-Codoped TiO₂ Having Different Surface-to-Volume Ratios

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Localization of Conduction Band Electrons in Polycrystalline Ti02 Studied by ESR

Cited by 77 publications

References 0 publications

EPR Investigations of G-C3N4/TiO2 Nanocomposites

EPR Investigations of G-C3N4/TiO2 Nanocomposites

Interplay between O2 and SnO2: Oxygen Ionosorption and Spectroscopic Evidence for Adsorbed Oxygen

Synthesis, Characterization, and Photocatalytic Activities of Nanoparticulate N, S-Codoped TiO2 Having Different Surface-to-Volume Ratios

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Product

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Interplay between O₂ and SnO₂: Oxygen Ionosorption and Spectroscopic Evidence for Adsorbed Oxygen

Synthesis, Characterization, and Photocatalytic Activities of Nanoparticulate N, S-Codoped TiO₂ Having Different Surface-to-Volume Ratios