Recent advances in making nano-sized TiO<sub>2</sub>visible-light active through rare-earth metal doping

Bingham, Sonny; Daoud, Walid A.

doi:10.1039/c0jm02271c

Cited by 260 publications

(120 citation statements)

References 53 publications

(90 reference statements)

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“…26 Doping with aliovalent ions is also a facile strategy to modify the electronic properties of electrospun titanium oxide. 17,18,[27][28][29][30] Nevertheless, only few papers report this procedure for application of the materials in LIB. 31 This is astonishing as, for example, Wang et al show that the conductivity, which is the crucial parameter for high performance cycling, can be raised two orders of magnitude by doping mesoporous TiO 2 with Nb.…”

Section: Introductionmentioning

confidence: 99%

Nb-Doped TiO₂ Nanofibers for Lithium Ion Batteries

et al. 2013

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Niobium doped nanofibers elaborated by facile, single-step electrospinning present higher rate capability in electrochemical cycling experiments than non-doped materials. This is attributed to the reduction of Li + diffusion path lengths and enhanced intimate inter-particle contact, in combination with improved intra-particle conductivity. Niobium doping has a significant effect on the electronic structure and provokes a substantial decrease in particle size.

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Section: Introductionmentioning

confidence: 99%

Nb-Doped TiO₂ Nanofibers for Lithium Ion Batteries

et al. 2013

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“…1 [32][33][34]. The diffraction from (400) has also observed which is due to Si substrate [7]. Therefore, the XRD pattern reveals the highly polycrystalline nature of the fabricated sample after annealing at the temperature of 800 o C. …”

Section: Xrd Analysismentioning

confidence: 97%

“…It has been reported that the impurity doping in the high band gap 1D TiO 2 semiconductor can reduce the band gap within the threshold limit [6]. TiO 2 is a prominent candidate as host material of Ln 3+ because of its chemical, thermal and mechanical properties [7]. The doping of rare earth oxides in the 1D TiO 2 semiconductor reduces its band gap [8,9].…”

Section: Introductionmentioning

confidence: 99%

Synthesis of Erbia Decorated Titania Nanowires Array Using Glancing Angle Deposition Technique

Devi¹

2017

IJRET

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“…UV light corresponds to only 4%-5% of the whole solar spectrum, while visible light constitutes 40% [24]. To reduce the intrinsic band gap of TiO 2 , several strategies have been tested including the incorporation of either metallic (e.g., Fe and Ni) or non-metallic (e.g., C, F, N, S, P, and B) atoms into the lattice of TiO 2 host materials [9,15,[25][26][27]. Metal doping has shown controversial photocatalytic activity results at both UV and visible wavelengths [28][29][30][31].…”

Section: Introductionmentioning

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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Recent advances in making nano-sized TiO₂visible-light active through rare-earth metal doping

Cited by 260 publications

References 53 publications

Nb-Doped TiO₂ Nanofibers for Lithium Ion Batteries

Nb-Doped TiO₂ Nanofibers for Lithium Ion Batteries

Synthesis of Erbia Decorated Titania Nanowires Array Using Glancing Angle Deposition Technique

Synthesis and Catalytic Applications of Non-Metal Doped Mesoporous Titania

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Recent advances in making nano-sized TiO2visible-light active through rare-earth metal doping

Cited by 260 publications

References 53 publications

Nb-Doped TiO2 Nanofibers for Lithium Ion Batteries

Nb-Doped TiO2 Nanofibers for Lithium Ion Batteries

Synthesis of Erbia Decorated Titania Nanowires Array Using Glancing Angle Deposition Technique

Synthesis and Catalytic Applications of Non-Metal Doped Mesoporous Titania

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Recent advances in making nano-sized TiO₂visible-light active through rare-earth metal doping

Nb-Doped TiO₂ Nanofibers for Lithium Ion Batteries

Nb-Doped TiO₂ Nanofibers for Lithium Ion Batteries