An Efficient Visible-Light-Sensitive Fe(III)-Grafted TiO<sub>2</sub> Photocatalyst

Yu, Huogen; Irie, Hiroshi; Shimodaira, Yoshiki; Hosogi, Yasuhiro; Kuroda, Yasushi; Miyauchi, Masahiro; Hashimoto, Kazuhito

doi:10.1021/jp1071956

Cited by 350 publications

(316 citation statements)

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“…Photocatalytic technologies have great potential as low cost, environmentally friendly catalysts for environmental depollution by destruction of organic pollutants 1,2 , removal of bacteria such as MRSA 3,4 and the interesting possibility of 30 solar hydrogen production from water splitting [5][6][7] . A leading material is titanium (IV) dioxide, TiO 2 , which is cheap, readily available and non-toxic.…”

Section: Introductionmentioning

confidence: 99%

TiO2 nanocluster modified-rutile TiO2 photocatalyst: a first principles investigation

2013

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Access to the full text of the published version may require a subscription. The clusters adsorb strongly at the surface giving adsorption energies from -2.7 eV to -6.7 eV. The resulting structures show a large number of new Ti-O bonds created between the cluster and the surface, so that the new bonds enhance the stability. The electronic density of states (EDOS) shows that the valence band edge is shifted upwards, due to new nanocluster derived states in this region, while the conduction band is unchanged and composed of the Ti 3d states from the surface. This 20 reduces the band gap over bare TiO 2 , potentially shifting light absorption into the visible region. The valence and conduction band composition of these heterostructures will favour spatial separation of electrons and holes after light excitation, thus giving improved photocatalytic properties in these novel structures. Rights © The Royal Society of Chemistry 2013. This is the Accepted Manuscript version of a published work that appeared in final form25

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Section: Introductionmentioning

confidence: 99%

TiO2 nanocluster modified-rutile TiO2 photocatalyst: a first principles investigation

2013

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“…In fact, it has been reported to both enhance electron/hole separation; thus, increasing the photocatalytic activity or increasing the rate of recombination of the charge carriers leading to a detrimental effect. The concentration of Fe 3+ ions has been shown to be a key factor since low loading increases the efficiency (Jin et al 2011;Yu et al 2010) while an high loading has generally the opposite effect (Elghniji et al 2012;Colmenares et al 2006;Wen et al 2012;Yu et al 2009;Rehman et al 2009;Fig. 7 Effect of the TiO 2 samples on the colony forming efficiency (CFE) on HaCaT cells exposed to 100 and 500 µg/mL of TiO 2 samples.…”

Section: Discussionmentioning

confidence: 99%

“…The photocatalytic efficiency of iron-doped TiO 2 is dependent upon the synthetic routes and the extent of loading. In fact, while an enhancement of the photocatalytic activity is observed for low loadings (Jin et al 2011;Yu et al 2010), high loadings may have a detrimental effect (Elghniji et al 2012; Colmenares et al 2006;Wen et al 2012;Yu et al 2009;Rehman et al 2009;Fabrega et al 2010). Manganese has also been proposed to decrease the photoreactivity of TiO 2 (Wakefield et al 2004).…”

Section: Introductionmentioning

confidence: 99%

Inhibition of the ROS-mediated cytotoxicity and genotoxicity of nano-TiO2 toward human keratinocyte cells by iron doping

et al. 2014

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Inhibition of the ROS-mediated cytotoxicity and genotoxicity of nano-TiO 2 toward human keratinocyte cells by iron doping J Nanopart Res (2014) Nano-TiO 2 powders are widely used in sunscreen lotions as UV filters in combination with other substances. The activation of TiO 2 by UV rays leads to the release of reactive oxygen species (ROS, e.g., hydroxyl radicals and singlet oxygen) which are potentially harmful. For this reason the TiO 2 particles are generally coated with inert materials (e.g., silica or alumina) that inhibit such reactivity. Alternatively, the release of ROS may be inhibited by introducing in the TiO 2 lattice doping elements. In the present study we report a new modification consisting in a wet impregnation of TiO 2 with iron salts followed by a thermal treatment that results in an inhibition of the surface reactivity. The insertion of iron ions also gradually reduces the ability of photo-activated TiO 2 to cleave DNA and proteins. At the same time, a clear inhibition of cyto-and geno-toxicity toward human (HaCaT) keratinocytes was observed. The data presented herein suggest the insertion of Fe 3+ ions at the surface of nano-TiO 2 as a promising strategy to reduce the photo-induced toxicity of nano-TiO 2 powders.

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“…12) 14) This system functions photocatalytically, because the interfacial charge transfer (IFCT)-induced holes in the valence band (VB) of TiO 2 decompose organic substances, while the Cu(I) [or Fe(II)] ions produced by IFCT appear to reduce adsorbed oxygen (O 2 ) through a multi-electron reduction process. 12)14) The induction of O 2 reduction by photo-generated Cu(I) [or Fe(II)] ions grafted on TiO 2 enables the conduction band (CB) of TiO 2 to be controlled, which led to the successful development of a visible light-sensitive CB-controlled Cu(II)/ Ti 1¹3x W x Ga 2x O 2 photocatalyst.…”

Section: Powder With Grafted Metal Ions (Copper(ii) [Cu(ii)] or Iron(mentioning

confidence: 99%

Hydrothermal synthesis of visible light-sensitive conduction band-controlled tungsten-doped titanium dioxide photocatalysts with copper ion-grafts

Kitta

Kumagai

et al. 2013

J. Ceram. Soc. Japan

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We prepared titanium dioxide (TiO 2 ) photocatalysts sensitive to visible light, namely copper(II) [Cu(II)]-grafted tungsten and gallium co-doped TiO 2 (Ti 1¹3x W x Ga 2x O 2 , x value is up to 0.12), based on the concept of narrowing the band gap of TiO 2 by positively shifting its conduction band (CB) edge to a lower energy level and the catalytic multi-electron reduction of oxygen by Cu(I) ions [H. Yu, H. Irie, K. Hashimoto, J. Am. Chem. Soc., 132, 6898 (2010)]. Using this approach, the optical band-gap energy of TiO 2 was decreased to ³2.8 eV, and band-gap narrowing was confirmed by measuring the action spectrum for oxygen evolution from water in the presence of iron ions [Fe(III), from FeCl 3 ]. The Cu(II)-grafted Ti 1¹3x W x Ga 2x O 2 (x = 0.12) photocatalyst effectively decomposed 2-propanol to carbon dioxide (CO 2 ) via acetone under visible light (400530 nm, 1 mW/cm 2 ) with a CO 2 -generation rate of 0.30¯mol/h. Grafting Cu(II) ions after the hydrochloric acid treatment of Ti 1¹3x W x Ga 2x O 2 (x = 0.12) increased the CO 2 -generation rate to 0.40¯mol/h.

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An Efficient Visible-Light-Sensitive Fe(III)-Grafted TiO₂ Photocatalyst

Cited by 350 publications

References 33 publications

TiO2 nanocluster modified-rutile TiO2 photocatalyst: a first principles investigation

TiO2 nanocluster modified-rutile TiO2 photocatalyst: a first principles investigation

Inhibition of the ROS-mediated cytotoxicity and genotoxicity of nano-TiO2 toward human keratinocyte cells by iron doping

Hydrothermal synthesis of visible light-sensitive conduction band-controlled tungsten-doped titanium dioxide photocatalysts with copper ion-grafts

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An Efficient Visible-Light-Sensitive Fe(III)-Grafted TiO2 Photocatalyst

Cited by 350 publications

References 33 publications

TiO2 nanocluster modified-rutile TiO2 photocatalyst: a first principles investigation

TiO2 nanocluster modified-rutile TiO2 photocatalyst: a first principles investigation

Inhibition of the ROS-mediated cytotoxicity and genotoxicity of nano-TiO2 toward human keratinocyte cells by iron doping

Hydrothermal synthesis of visible light-sensitive conduction band-controlled tungsten-doped titanium dioxide photocatalysts with copper ion-grafts

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An Efficient Visible-Light-Sensitive Fe(III)-Grafted TiO₂ Photocatalyst