Defect Chemistry of Titanium Dioxide. Application of Defect Engineering in Processing of TiO<sub>2</sub>-Based Photocatalysts

Nowotny, M. K.; Sheppard, L. R.; Бак, Т.; Nowotny, Janusz

doi:10.1021/jp077275m

Cited by 534 publications

(583 citation statements)

References 115 publications

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“…A number of studies 7,8,16,44,48,49,59 have already shown the importance of the lattice defects in conjunction with PCA either in the case of pristine or heterojunction catalysts, where they can be identied through optical properties. We have performed PL spectroscopy on the CSHJ nanobers (Fig.…”

Section: Photocatalytic Activity Of Core-shell Heterojunction Nanobersmentioning

confidence: 99%

Selective isolation of the electron or hole in photocatalysis: ZnO–TiO2 and TiO2–ZnO core–shell structured heterojunction nanofibers via electrospinning and atomic layer deposition

et al. 2014

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Heterojunctions are a well-studied material combination in photocatalysis studies, the majority of which aim to improve the efficacy of the catalysts. Developing novel catalysts begs the question of which photo-generated charge carrier is more efficient in the process of catalysis and the associated mechanism. To address this issue we have fabricated core-shell heterojunction (CSHJ) nanofibers from ZnO and TiO 2 in two combinations where only the 'shell' part of the heterojunction is exposed to the environment to participate in the photocatalysis. Core and shell structures were fabricated via electrospinning and atomic layer deposition, respectively which were then subjected to calcination. These CSHJs were characterized and studied for photocatalytic activity (PCA). These two combinations expose electrons or holes selectively to the environment. Under suitable illumination of the ZnO-TiO 2 CSHJ, e/h pairs are created mainly in TiO 2 and the electrons take part in catalysis (i.e. reduce the organic dye) at the conduction band or oxygen vacancy sites of the 'shell', while holes migrate to the core of the structure. Conversely, holes take part in catalysis and electrons diffuse to the core in the case of a TiO 2 -ZnO CSHJ. The results further revealed that the TiO 2 -ZnO CSHJ shows $1.6 times faster PCA when compared to the ZnO-TiO 2 CSHJ because of efficient hole capture by oxygen vacancies, and the lower mobility of holes.

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Section: Photocatalytic Activity Of Core-shell Heterojunction Nanobersmentioning

confidence: 99%

Selective isolation of the electron or hole in photocatalysis: ZnO–TiO2 and TiO2–ZnO core–shell structured heterojunction nanofibers via electrospinning and atomic layer deposition

et al. 2014

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“…In connection to lattice defects, depending on the type and energetic location of the defect, their character is determined to capture either an electron or a hole, thereby delaying the recombination process. [1][2][3][4]6,[8][9][10][11][12][13] As a consequence, the captured or free charge carrier participates in photocatalytic activity (PCA), in which the catalysis occurs at the conduction band (CB), valance band (VB) and the defect site, if available on the surface. 4,8 Note that the defects form intermediate bands within the band gap, which allow visible light harvest especially in the case of wide band gap semiconductors.…”

Section: Introductionmentioning

confidence: 99%

“…1,4,8,[15][16][17] The lattice defects connected to PCA are basically intrinsic (vacancies, interstitials, anti-site) or extrinsic (induced by impurities) in nature. 1,4,6,[8][9][10][11][12][13]15,18 However, it is rather hard, though intriguing, to determine which defect is more benecial for PCA, especially in the context of ZnO because controlling the defect density and maintaining a balance among various defect types is quite challenging. 15 On the other hand, dominant defect density can compromise optical quality; nevertheless, it increases PCA, as recently reported by us.…”

Section: Introductionmentioning

confidence: 99%

“…25,26 Note that the controllability of the defect density depends on the type of defect and the semiconductor itself. 1,6,[8][9][10][11][12][13] In the context of ZnO, numerous studies deal with V O s, 4,8,10,11,13,21 which is not the case with Zn i s. It is also notable that the balance between the relative densities of Zn i s and V O s is still challenging. 15 The presence of Zn i s and V O s in ZnO can be easily identied by simple photoluminescence (PL) experiments, [15][16][17]27 indicated by blue and green emissions, respectively.…”

Section: Introductionmentioning

confidence: 99%

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Role of zinc interstitials and oxygen vacancies of ZnO in photocatalysis: a bottom-up approach to control defect density

et al. 2014

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Oxygen vacancies (V O s) in ZnO are well-known to enhance photocatalytic activity (PCA) despite various other intrinsic crystal defects. In this study, we aim to elucidate the effect of zinc interstitials (Zn i ) and V O s on PCA, which has applied as well as fundamental interest. To achieve this, the major hurdle of fabricating ZnO with controlled defect density requires to be overcome, where it is acknowledged that defect level control in ZnO is significantly difficult. In the present context, we fabricated nanostructures and thoroughly characterized their morphological (SEM, TEM), structural (XRD, TEM), chemical (XPS) and optical (photoluminescence, PL) properties. To fabricate the nanostructures, we adopted atomic layer deposition (ALD), which is a powerful bottom-up approach. However, to control defects, we chose polysulfone electrospun nanofibers as a substrate on which the non-uniform adsorption of ALD precursors is inevitable because of the differences in the hydrophilic nature of the functional groups. For the first 100 cycles, Zn i s were predominant in ZnO quantum dots (QDs), while the presence of V O s was negligible. As the ALD cycle number increased, V O s were introduced, whereas the density of Zn i remained unchanged. We employed PL spectra to identify and quantify the density of each defect for all the samples. PCA was performed on all the samples, and the percent change in the decay constant for each sample was juxtaposed with the relative densities of Zn i s and V O s. A logical comparison of the relative defect densities of Zn i s and V O s suggested that the former are less efficient than the latter because of the differences in the intrinsic nature and the physical accessibility of the defects. Other reasons for the efficiency differences were elaborated.

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“…Among these factors, making defects in photocatalysts has been found to be an effective method for improving the activity via changing the charge transfer and band structure. 16,17 Especially, oxygen-vacancy can serve as photoinduced charge traps and modify the band structure of semiconductor photocatalysts, which is conductive to the enhanced photocatalytic activity. [18][19][20] The light absorption range of semiconductor materials can be enhanced or expanded by introducing oxygen vacancies, which results in the extended light absorption spectra and band gap narrowing.…”

Section: Introductionmentioning

confidence: 99%

Surface oxygen-vacancy induced photocatalytic activity of La(OH)₃ nanorods prepared by a fast and scalable method

Dong

Xiao

Jiang

et al. 2015

Phys. Chem. Chem. Phys.

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Uniform one-dimensional defective La(OH) 3 nanorods were synthesized by a facile, fast and scalable method. This simple method avoids treatment at high temperature, utility of surfactants or templates, and can be finished within a short time. The results indicate that oxygen-vacancies were formed in La(OH) 3 nanorods, which could extend the photoresponse range. The XPS, PL, solid state ESR measurements and DFT calculations revealed the pivotal role of oxygen-vacancy in the formation of an impurity level in the band gap of La(OH) 3 . The as-prepared La(OH) 3 nanorods exhibited efficient photocatalytic activity in the removal of NO at the ppb-level under ultraviolet illumination. The highly enhanced photocatalytic activity of La(OH) 3 nanorods could be ascribed to the synergy of the lower impurity level below the conduction band and the high separation efficiency of photogenerated electron-hole pairs. DMPO-ESR spin trapping results imply that the hydroxyl radicals are the main reactive species that are responsible for NO photooxidation. On the basis of combined experimental and theoretical investigation, an oxygen vacancy-mediated photocatalysis mechanism of defective La(OH) 3 nanorods was proposed. This work could not only provide a fast and environmentally friendly approach for the synthesis of nanostructured photocatalysts, but also new insights into the understanding of the role of vacancy in semiconductor photocatalysis.

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Defect Chemistry of Titanium Dioxide. Application of Defect Engineering in Processing of TiO₂-Based Photocatalysts

Cited by 534 publications

References 115 publications

Selective isolation of the electron or hole in photocatalysis: ZnO–TiO2 and TiO2–ZnO core–shell structured heterojunction nanofibers via electrospinning and atomic layer deposition

Selective isolation of the electron or hole in photocatalysis: ZnO–TiO2 and TiO2–ZnO core–shell structured heterojunction nanofibers via electrospinning and atomic layer deposition

Role of zinc interstitials and oxygen vacancies of ZnO in photocatalysis: a bottom-up approach to control defect density

Surface oxygen-vacancy induced photocatalytic activity of La(OH)₃ nanorods prepared by a fast and scalable method

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Defect Chemistry of Titanium Dioxide. Application of Defect Engineering in Processing of TiO2-Based Photocatalysts

Cited by 534 publications

References 115 publications

Selective isolation of the electron or hole in photocatalysis: ZnO–TiO2 and TiO2–ZnO core–shell structured heterojunction nanofibers via electrospinning and atomic layer deposition

Selective isolation of the electron or hole in photocatalysis: ZnO–TiO2 and TiO2–ZnO core–shell structured heterojunction nanofibers via electrospinning and atomic layer deposition

Role of zinc interstitials and oxygen vacancies of ZnO in photocatalysis: a bottom-up approach to control defect density

Surface oxygen-vacancy induced photocatalytic activity of La(OH)3 nanorods prepared by a fast and scalable method

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Defect Chemistry of Titanium Dioxide. Application of Defect Engineering in Processing of TiO₂-Based Photocatalysts

Surface oxygen-vacancy induced photocatalytic activity of La(OH)₃ nanorods prepared by a fast and scalable method