Physiochemical properties of n-n heterostructured TiO<sub>2</sub>/Mo-TiO<sub>2</sub> composites and their photocatalytic degradation of gaseous toluene

Cui, Mifen; Pan, Shuai; Tang, Zhe; Chen, Xian; Qiao, Xu; Xu, Qingping

doi:10.1080/09542299.2017.1315617

Cited by 24 publications

(11 citation statements)

References 44 publications

(44 reference statements)

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“…Theoretically, by offering more valence electrons easily photo-incited and converting to free carriers, Mo doping with low concentration introduces a donor level below the conduction band of TiO2, resulting in a narrower band gap [7]. The shifted band gap can be evaluated from the absorption spectrum by the Tauc method [26,30]. The estimated band gap of undoped TiO2 is 3.24 eV, agreeing with the typical value of intrinsic pure TiO2 [20].…”

Section: Resultsmentioning

confidence: 55%

“…In numerical terms, the ionic radius of Ti 4+ (0.068 nm) is very close to the ionic radius of Mo 6+ (0.062 nm), and when the amount of doping is not too high (0.5 at.%), most of Mo 6+ ions replace Ti 4+ as substitutional impurities. In the case of heavy doping (1.0 at.%), excess Mo enters the lattice only in the form of interstitial atoms, which aggravates the lattice deformation and suppresses grain growth [26]. Some researchers suggest that the doping of Mo inhibits growth of crystals due to induced structure defects and hinders the transformation from anatase to rutile of TiO 2 at the same time [7,27].…”

Section: Resultsmentioning

confidence: 99%

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Enhanced Photoelectrochemical Properties from Mo-Doped TiO2 Nanotube Arrays Film

Xue

Luo

et al. 2020

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Mo-doped TiO2 nanotube arrays are prepared successfully by a combined method of direct current (DC) magnetron sputtering and anodic oxidation. The doping amount of Mo can be modified by changing the number of molybdenum blocks on the Ti target while a Ti–Mo alloy film is prepared by magnetron sputtering on a metal Ti substrate, following a Mo-doped TiO2 nanotube array grown by anodization. Morphology test shows that the doping of Mo could inhibit the phase transition and growth of crystal of TiO2. X-ray photoelectron spectroscopy (XPS) results show that Mo has successfully been embedded in the TiO2 crystal lattice and mainly exists in the valence states of Mo6+. Mo-doping samples show slightly increased visible light absorption as the red shift of TiO2 absorption edge with the band gap dropping from 3.24 to 3.16 eV with 0.5 at.% Mo doping. The enhanced photocurrent is demonstrated for a 0.5 at.% Mo-doped TiO2 electrode. Through photoelectric performance testing under UV-visible light irradiation, the nanotube array film with a Mo-doped content of 0.5% produced the maximum photocurrent density, which is about four times the undoped TiO2 nanotube array film, exhibiting a considerable photoelectric effect gain. The controllable Mo doping TiO2 nanotube array film prepared by this combining technique is expected as a promising material for efficient applications in photoelectric conversion.

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Section: Resultsmentioning

confidence: 55%

Section: Resultsmentioning

confidence: 99%

Enhanced Photoelectrochemical Properties from Mo-Doped TiO2 Nanotube Arrays Film

Xue

Luo

et al. 2020

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“…4 Therefore, an external UV light source is required for their activation, which is not a cost-effective method. However, various hybrid composites synthesized by combining doping of transition metals (Ti, Fe, Ru, Au, and Mo) [8][9][10][11] and/or non-metals (C, N, and S) [12][13][14] can improve the photocatalytic performance, but, high preparation costs, non-renewability, and risks of secondary pollution prevent their large-scale application. Therefore, more and more attention has been applied to giving a stable platform for photocatalytic nanoparticles by incorporating secondary materials, which can improve the recoverability and visible light sensitivity of the photocatalysts.…”

Section: Introductionmentioning

confidence: 99%

Recent progress in biochar-supported photocatalysts: synthesis, role of biochar, and applications

2018

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“…Moreover, the photocatalytic performance restricts its development and application: firstly, the band gap of 3.2 eV limits it to using only ultraviolet light below 387.5 nm in wavelength [8]. Secondly, the electron and hole produced by the light excitation of TiO 2 recombine very easily [9,10]. Therefore, developing preparation technology of TiO 2 with good dispersion and a uniform particle size and exploring a way to broaden the light response range and inhibit the electron and hole recombination of TiO 2 are the key problems which need to be solved urgently in order to develop the commercialization and advanced application of nano-TiO 2 .…”

Section: Introductionmentioning

confidence: 99%

Preparation of TiO2 and Fe-TiO2 with an Impinging Stream-Rotating Packed Bed by the Precipitation Method for the Photodegradation of Gaseous Toluene

et al. 2019

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Nano-TiO2 has always been one of the most important topics in the research of photocatalysts due to its special activity and stability. However, it has always been difficult to obtain nano-TiO2 with high dispersion, a small particle size and high photocatalytic activity. In this paper, nano-TiO2 powder was prepared by combining the high-gravity technique and direct precipitation method in an impinging stream-rotating packed bed (IS-RPB) reactor followed by Fe3+ in-situ doping. TiOSO4 and NH3·H2O solutions were cut into very small liquid microelements by high-speed rotating packing, and the mass transfer and microscopic mixing of the nucleation and growth processes of nano-TiO2 were strengthened in IS-RPB, which was beneficial to the continuous production of high quality nano-TiO2. Pure TiO2 and iron-doped nano-TiO2 (Fe-TiO2) were obtained in IS-RPB and were investigated by means of X-ray diffraction (XRD), Raman, scanning electron microscopy (SEM), transmission electron microscopy (TEM), X-ray photoelectron spectroscopy (XPS), ultraviolet-visible diffuse reflectance spectroscopy (UV-vis DRS) and Brunauer–Emmett–Teller (BET) analysis, which found that pure TiO2 had a particle size of about 12.5 nm, good dispersibility and a complete anatase crystal at the rotating speed of packing of 800 rpm and calcination temperature of 500 °C. The addition of Fe3+ did not change the crystalline structure of TiO2. Iron was highly dispersed in TiO2 without the detection of aggregates and was found to exist in a positive trivalent form by XPS. With the increase of iron doping, the photoresponse range of TiO2 to visible light was broadened from 3.06 eV to 2.26 eV. The degradation efficiency of gaseous toluene by Fe-TiO2 under ultraviolet light was higher than that of pure TiO2 and commercial P25 due to Fe3+ effectively suppressing the recombination of TiO2 electrons and holes; the highest efficiency produced by 1.0% Fe-TiO2 was 95.7%.

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Physiochemical properties of n-n heterostructured TiO₂/Mo-TiO₂ composites and their photocatalytic degradation of gaseous toluene

Cited by 24 publications

References 44 publications

Enhanced Photoelectrochemical Properties from Mo-Doped TiO2 Nanotube Arrays Film

Enhanced Photoelectrochemical Properties from Mo-Doped TiO2 Nanotube Arrays Film

Recent progress in biochar-supported photocatalysts: synthesis, role of biochar, and applications

Preparation of TiO2 and Fe-TiO2 with an Impinging Stream-Rotating Packed Bed by the Precipitation Method for the Photodegradation of Gaseous Toluene

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Physiochemical properties of n-n heterostructured TiO2/Mo-TiO2 composites and their photocatalytic degradation of gaseous toluene

Cited by 24 publications

References 44 publications

Enhanced Photoelectrochemical Properties from Mo-Doped TiO2 Nanotube Arrays Film

Enhanced Photoelectrochemical Properties from Mo-Doped TiO2 Nanotube Arrays Film

Recent progress in biochar-supported photocatalysts: synthesis, role of biochar, and applications

Preparation of TiO2 and Fe-TiO2 with an Impinging Stream-Rotating Packed Bed by the Precipitation Method for the Photodegradation of Gaseous Toluene

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Physiochemical properties of n-n heterostructured TiO₂/Mo-TiO₂ composites and their photocatalytic degradation of gaseous toluene