Visible Light Active Platinum-Ion-Doped TiO<sub>2</sub> Photocatalyst

Kim, Soonhyun; Hwang, Seong Ju; Choi, Wonyong

doi:10.1021/jp055278y

Cited by 383 publications

(222 citation statements)

References 54 publications

(106 reference statements)

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“…However, the majority of the simple and mixed-metal oxides photocatalysts are primarily active for H 2 production under UV irradiation (l < 385 nm or E g $ 3.0 eV) present in only a small portion of solar light. More recently, there is a focused effort on the development of photocatalysts that are capable of using visible light (l ¼ 400-700 nm) for the photocatalytic production of H 2 including transition metal doping (e.g., platinum, 29 chromium, 30 and vanadium 31 ) and nonmetallic element doping (e.g., nitrogen, [32][33][34][35] sulfur, 36,37 and carbon 35,38 ). CdS, n-type semiconductor with E g ¼ 2.4 eV, has been shown to have photocatalytic activity for H 2 production under visible light irradiation, although, sacrificial electron donors such as C 2 H 5 OH, 39 HS À , 40,41 or SO 3 2À 19 are used to obtain measurable rates of H 2 production and to avoid the photocorrosion of CdS in the presence of O 2 .…”

Section: -17mentioning

confidence: 99%

Photocatalytic production of hydrogen on Ni/NiO/KNbO3/CdS nanocomposites using visible light

et al. 2008

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3. Enhanced activity is most likely due to effective charge separation of photogenerated electrons and holes in CdS that is achieved by electron injection into the conduction band of KNbO 3 and the reduced states of niobium (e.g., Nb(IV) and Nb(III)) are shown to contribute to enhanced reactivity in the KNbO 3 composites by mediating effective electron transfer to bound protons. We also observed that the efficient attachment of Q-size CdS and the deposition of nickel on the KNbO 3 surface increases H 2 production rates. Other factors that influence the rate of H 2 production including the nature of the electron donors and the solution pH were also determined. The Ni/NiO/KNbO 3 /CdS nanocomposite system appears to be a promising candidate for possible practical applications including the production of H 2 under visible light.

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Section: -17mentioning

confidence: 99%

Photocatalytic production of hydrogen on Ni/NiO/KNbO3/CdS nanocomposites using visible light

et al. 2008

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“…Heterogeneous catalysis has been successfully employed for the degradation of various families of hazardous materials. Titanium dioxide (TiO 2 ), due to its non-toxic, inexpensive, and high reactive nature, has been extensively investigated as a heterogeneous photocatalyst for the remediation of contaminated environment (Hassan et al 2014;Harbi et al 2015;Kim et al 2005). The advantage of TiO 2 as photocatalyst is that organic pollutants are usually completely mineralized to non-toxic substances such as CO 2 , HCl and water and thus the reactions do not suffer the drawbacks of photolysis reactions in terms of the production of intermediate products.…”

Section: Introductionmentioning

confidence: 99%

Parameters affecting the photocatalytic degradation of dyes using TiO2: a review

2015

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Traditional chemical, physical and biological processes for treating wastewater containing textile dye have such disadvantages as high cost, high energy requirement and generation of secondary pollution during treatment process. The advanced oxidation processes technology has been attracting growing attention for the decomposition of organic dyes. Such processes are based on the light-enhanced generation of highly reactive hydroxyl radicals, which oxidize the organic matter in solution and convert it completely into water, CO 2 and inorganic compounds. In this presentation, the photocatalytic degradation of dyes in aqueous solution using TiO 2 as photocatalyst under solar and UV irradiation has been reviewed. It is observed that the degradation of dyes depends on several parameters such as pH, catalyst concentration, substrate concentration and the presence of oxidants. Reaction temperature and the intensity of light also affect the degradation of dyes. Particle size, BETsurface area and different mineral forms of TiO 2 also have influence on the degradation rate.

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“…Noble metals act as passive sinks for electrons to promote the interfacial charge transfer process and enhance the quantum efficiency of photocatalytic system [29,[236][237][238]. In addition, metal nanoparticles show plasmonic effects and provide hot electrons into the conduction band of titania.…”

Section: Future Directionsmentioning

confidence: 99%

Synthesis and Catalytic Applications of Non-Metal Doped Mesoporous Titania

et al. 2017

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Mesoporous titania (mp-TiO 2 ) has drawn tremendous attention for a diverse set of applications due to its high surface area, interfacial structure, and tunable combination of pore size, pore orientation, wall thickness, and pore connectivity. Its pore structure facilitates rapid diffusion of reactants and charge carriers to the photocatalytically active interface of TiO 2 . However, because the large band gap of TiO 2 limits its ability to utilize visible light, non-metal doping has been extensively studied to tune the energy levels of TiO 2 . While first-principles calculations support the efficacy of this approach, it is challenging to efficiently introduce active non-metal dopants into the lattice of TiO 2 . This review surveys recent advances in the preparation of mp-TiO 2 and their doping with non-metal atoms. Different doping strategies and dopant sources are discussed. Further, co-doping with combinations of non-metal dopants are discussed as strategies to reduce the band gap, improve photogenerated charge separation, and enhance visible light absorption. The improvements resulting from each doping strategy are discussed in light of potential changes in mesoporous architecture, dopant composition and chemical state, extent of band gap reduction, and improvement in photocatalytic activities. Finally, potential applications of non-metal-doped mp-TiO 2 are explored in water splitting, CO 2 reduction, and environmental remediation with visible light.

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Visible Light Active Platinum-Ion-Doped TiO₂ Photocatalyst

Cited by 383 publications

References 54 publications

Photocatalytic production of hydrogen on Ni/NiO/KNbO3/CdS nanocomposites using visible light

Photocatalytic production of hydrogen on Ni/NiO/KNbO3/CdS nanocomposites using visible light

Parameters affecting the photocatalytic degradation of dyes using TiO2: a review

Synthesis and Catalytic Applications of Non-Metal Doped Mesoporous Titania

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Visible Light Active Platinum-Ion-Doped TiO2 Photocatalyst

Cited by 383 publications

References 54 publications

Photocatalytic production of hydrogen on Ni/NiO/KNbO3/CdS nanocomposites using visible light

Photocatalytic production of hydrogen on Ni/NiO/KNbO3/CdS nanocomposites using visible light

Parameters affecting the photocatalytic degradation of dyes using TiO2: a review

Synthesis and Catalytic Applications of Non-Metal Doped Mesoporous Titania

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Product

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Visible Light Active Platinum-Ion-Doped TiO₂ Photocatalyst