TiO<sub>2</sub>−WO<sub>3</sub> Photoelectrochemical Anticorrosion System with an Energy Storage Ability

Tatsuma, Tetsu; Saitoh, Shu‐ichi; Ohko, Yoshihisa; Fujishima, Akira

doi:10.1021/cm010024k

Cited by 337 publications

(196 citation statements)

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“…In order to retain its useful effects even after dark, we have developed photocatalysts with energy storage abilities. [3][4][5][6][7][8][9][10][11][12][13][14][15] They can store surplus charges from photocatalysts in rechargeable materials during the day, and the stored charges are used to carry on redox reactions during the night.…”

Section: Introductionmentioning

confidence: 99%

“…We have combined TiO 2 3-8 or SrTiO 3 9 as well as Au-TiO 2 , 10 which exhibits photocatalytic activity on the basis of plasmoninduced charge separation, [16][17][18][19] with a rechargeable material such as WO 3 , [3][4][5][6]9,10 MoO 3 , 7,10 or H 3 PW 12 O 40 (PWA), 8 which undergoes redox reactions at negative potentials. Those photocatalysts with reductive energy storage abilities retain some photocatalytic effects based on cathodic reactions, such as anti-bacterial 6 and anticorrosion 3 effects, even after dark.…”

Section: Introductionmentioning

confidence: 99%

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Metal Oxides and Hydroxides as Rechargeable Materials for Photocatalysts with Oxidative Energy Storage Abilities

Takahashi

Tatsuma

2014

Electrochemistry

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NiO, Co(OH) 2 , Ir oxide, and Ru oxide were combined as rechargeable materials with TiO 2 or Pt-TiO 2 photocatalyst to obtain novel photocatalysts with oxidative energy storage abilities. NiO, which is more stable than the conventional storage material, Ni(OH) 2 , showed similar characteristics to those of Ni(OH) 2 . The redox potential of Co(OH) 2 was more negative, and those of Ir oxide and Ru oxide were more positive than that of Ni(OH) 2 . The photoelectrochemically charged Ir oxide was reduced by acetone, acetic acid, Br − , and water. The diversity of energy storage materials was accordingly improved in terms of the reaction potential and stability.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Metal Oxides and Hydroxides as Rechargeable Materials for Photocatalysts with Oxidative Energy Storage Abilities

Takahashi

Tatsuma

2014

Electrochemistry

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“…The photocatalytic activity of WO 3 -TiO 2 films was found to be three times higher than that of pure TiO 2 films for the gas-phase oxidation of 2-propanol [18]. A TiO 2 coating was coupled with a WO 3 ''electron pool'' in the design of a photoelectrochemical anticorrosion system with built-in energy storage capability [19]. A WO 3 -TiO 2 buffer layer between the transparent conducting oxide substrate and a P25 TiO 2 layer was found to be beneficial in the operation of a Ru(II)-dye sensitized solar cell [20].…”

Section: Introductionmentioning

confidence: 99%

Erratum to: Sol–gel synthesis of mesoporous WO3–TiO2 composite thin films for photochromic devices

Djaoued

Balaji

Beaudoin

2013

J Sol-Gel Sci Technol

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Mesoporous WO 3 -TiO 2 composite films were prepared by a sol gel based two stage dip coating method and subsequent annealing at 450, 500 and 600°C. An organically modified silicate based templating strategy was adopted in order to obtain a mesoporous structure. The composite films were prepared on ITO coated glass substrates. The porosity, morphology, and microstructures of the resultant products were characterized by scanning electron microscopy, N 2 adsorption-desorption measurements, l-Raman spectroscopy and X-ray diffraction. Calcination of the films at 450, and 500°C resulted in mixed hexagonal (h) plus monoclinic phases, and pure monoclinic (m) phase of WO 3 , respectively. The degree of crystallization of TiO 2 present in these composite films was not evident. The composite films annealed at 600°C, however, consist of orthorhombic (o) WO 3 and anatase TiO 2 . It was found that the o-WO 3 phase was stabilized by nanocrystalline anatase TiO 2 . The thus obtained mesoporous WO 3 -TiO 2 composite films were dye sensitized and applied for the construction of photochromic devices. The device constructed using dye sensitized WO 3 -TiO 2 composite layer heat treated at 600°C showed an optical modulation of 51 % in the NIR region, whereas the devices based on the composite layers heat treated at 450, and 500°C showed only a moderate optical modulation of 24.9, and 38 %, respectively. This remarkable difference in the transmittance response is attributed to nanocrystalline anatase TiO 2 embedded in the orthorhombic WO 3 matrix of the WO 3 -TiO 2 composite layer annealed at 600°C.

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“…The TiO 2 coating plays the role of providing electrons like a sacrificial anode in cathodic protection. Subsequently, Fujishima et al 5 studied the mechanism of the photoelectrochemical cathodic protection of TiO 2 -WO 3 in 3 wt% NaCl solution with pH = 5. So far, TiO 2 -protection of metals using sunlight has been a focus of great attention as a possible means for converting solar energy to electrical energy by generating the required negative electrode potential.…”

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confidence: 99%

Long-Term Photoelectrochemical Cathodic Protection by Co(OH)₂-Modified TiO₂on 304 Stainless Steel in Marine Environment

Xie

Liu

Chen

et al. 2018

J. Electrochem. Soc.

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The long-term photoelectrochemical cathodic protection by Co(OH) 2 -surface modified TiO 2 of anatase nanotubes and rutile type, prepared by anodic oxidation has been studied in aqueous 3.5 wt% NaCl solution. Electrochemical measurements have been used to evaluate the photoelectrochemical protective properties of both Co(OH) 2 -modified TiO 2 coupled with 304 stainless steel in 3.5 wt% NaCl solution under illumination and in the dark. Morphologies, crystal structures, surface compositions, and light response range of both Co(OH) 2 -surface modified TiO 2 films before and after immersion were characterized, respectively, by scanning electron microscopy (SEM), transmission electron microscopy (TEM), X-ray diffraction (XRD), X-ray photoelectron spectroscopy (XPS), UV-Vis spectrophotometry. The results show that the photogenerated electrode potential of both types of TiO 2 films modified with Co(OH) 2 is more negative affording protection of 304 stainless steel than that of the non-modified TiO 2 under illumination. These TiO 2 films provide a long period (12 h) of protection. The anatase-TiO 2 nanotube film always shows a better protection performance than rutile-TiO 2 film. In recent years, photocatalysis has been broadly used in solar cells, for degradation of pollutants, splitting of water, air purification, and corrosion protection of metals.1-3 The latter application has attracted our attention because of its environmental advantages.In 1990s, Tsujikawa and Yuan 4 first proposed the method of photoelectrochemical cathodic protection of metals by photocatalytic materials. They reported the more negative corrosion potential of TiO 2 -coated 304 stainless steel or carbon steel under UV irradiation than that of bare steel. The TiO 2 coating plays the role of providing electrons like a sacrificial anode in cathodic protection. Subsequently, Fujishima et al.5 studied the mechanism of the photoelectrochemical cathodic protection of TiO 2 -WO 3 in 3 wt% NaCl solution with pH = 5. So far, TiO 2 -protection of metals using sunlight has been a focus of great attention as a possible means for converting solar energy to electrical energy by generating the required negative electrode potential. Photoelectrochemical cathodic protection has become an active research field of metal corrosion protection. It has attracted numerous studies and yielded new technologies. [6][7][8][9][10][11][12][13] Many metal oxides and sulfides, such as TiO 2 , 4,9 ZnO, 14 SnO 2 15 and CdS, 16 have been investigated as common photocatalyst materials. TiO 2 is most widely used in current applications because of its high catalytic activity, good resistance to photocorrosion, chemical stability, cheapness, and non-toxicity. 4,[17][18][19] Of the three crystal modifications of TiO 2 , the wide bandgap forms anatase (3.2 eV) and rutile (3.0 eV) are mainly employed in photocatalytic reactions. 20,21 However, photocatalytic materials still have problems in the marine environment. Corrosion is a gradual and long-term destruction of materials. Therefore...

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TiO₂−WO₃ Photoelectrochemical Anticorrosion System with an Energy Storage Ability

Cited by 337 publications

References 14 publications

Metal Oxides and Hydroxides as Rechargeable Materials for Photocatalysts with Oxidative Energy Storage Abilities

Metal Oxides and Hydroxides as Rechargeable Materials for Photocatalysts with Oxidative Energy Storage Abilities

Erratum to: Sol–gel synthesis of mesoporous WO3–TiO2 composite thin films for photochromic devices

Long-Term Photoelectrochemical Cathodic Protection by Co(OH)₂-Modified TiO₂on 304 Stainless Steel in Marine Environment

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TiO2−WO3 Photoelectrochemical Anticorrosion System with an Energy Storage Ability

Cited by 337 publications

References 14 publications

Metal Oxides and Hydroxides as Rechargeable Materials for Photocatalysts with Oxidative Energy Storage Abilities

Metal Oxides and Hydroxides as Rechargeable Materials for Photocatalysts with Oxidative Energy Storage Abilities

Erratum to: Sol–gel synthesis of mesoporous WO3–TiO2 composite thin films for photochromic devices

Long-Term Photoelectrochemical Cathodic Protection by Co(OH)2-Modified TiO2on 304 Stainless Steel in Marine Environment

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TiO₂−WO₃ Photoelectrochemical Anticorrosion System with an Energy Storage Ability

Long-Term Photoelectrochemical Cathodic Protection by Co(OH)₂-Modified TiO₂on 304 Stainless Steel in Marine Environment