Kinetic Study on the Crystal Transformation of Fe-Doped TiO<sub>2</sub> via In Situ High-Temperature X-ray Diffraction and Transmission Electron Microscopy

Zhang, Lu; Luo, Xiaoyan; Zhang, Jiandong; Long, Youwen; Xue, Xin; Xu, Benjun

doi:10.1021/acsomega.0c05609

Cited by 10 publications

(10 citation statements)

References 28 publications

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“…72 Zhang et al recently reported that pure TiO 2 powder matches the first-order model. 72 Other models have been adopted to describe the ART process for the anatase powders. 39,44,73,74 A model based on a uniform spherical inward growth of spherical particles follows .…”

Section: Resultsmentioning

confidence: 90%

Phase transition of individual anatase TiO₂ microcrystals with large percentage of (001) facets: a Raman mapping and SEM study

Lü

Zhu

Birmingham

et al. 2023

Phys. Chem. Chem. Phys.

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Section: Resultsmentioning

confidence: 90%

Phase transition of individual anatase TiO₂ microcrystals with large percentage of (001) facets: a Raman mapping and SEM study

Lü

Zhu

Birmingham

et al. 2023

Phys. Chem. Chem. Phys.

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“…The rutile phase is augmented by the Ir dopant, which favors the formation of oxygen vacancies in the crystal lattice. Moreover, the XRD results clearly demonstrated that the Ir doping promotes the rutile formation at low calcination temperatures, through decreasing the activation energy for the ART …”

Section: Results and Discussionmentioning

confidence: 96%

“…The broadening of Raman modes for the samples with high Ir % demonstrates the increase in anharmonicity with the cell volume . The low-temperature rutile formation indicates that the activation energy of Ir-TiO 2 samples for phase transition is lower than that of pure TiO 2 . The substitution of the Ir dopant in the TiO 2 crystal lattice or TiO 6 2– octahedra could lead to the d–d electronic transition .…”

Section: Results and Discussionmentioning

confidence: 97%

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New Insights into Crystal Defects, Oxygen Vacancies, and Phase Transition of Ir-TiO₂

et al. 2021

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The impact of iridium (Ir) doping on the oxygen vacancies, relative stability, crystallite size, surface area, and anatase-to-rutile transition of TiO 2 was comprehensively investigated in this study. Ir-doped TiO 2 (Ir-TiO 2 ) was synthesized through a sol−gel technique, and the samples were annealed in the temperature range of 400−700 °C. Density functional theory calculations showed that the energy cost of an oxygen vacancy formation for Ir-TiO 2 was lower, as compared to that of the pristine TiO 2 , with the formation of Ir 3+ states in the band gap. Ir could provide more rutile nucleation sites and accelerate the rutile formation through the crystal strain relaxation. The entropy of mixing was reduced by the incorporation of Ir, which could induce the rutile formation with an increase in Gibbs free energy at temperatures below the normal phase transition temperature for pure TiO 2 . The rutile formation of Ir-TiO 2 could take place at a low annealing temperature (400 °C) compared to pristine TiO 2 (600 °C), indicating that the activation energy for phase transition could be decreased by incorporating Ir. XPS revealed the spin−orbit coupling of Ir 4f peaks, Ir 4f 7/2 (61.96 eV) and Ir 4f 5/2 (64.77 eV), due to the presence of Ir 3+ . Raman studies indicated the formation of charge-compensating oxygen vacancies and the presence of d states by Ir doping. It is concluded that the defects originated because the incorporation of Ir could facilitate rutile nucleation sites and thereby accelerate the phase transition through strain relaxation.

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“…This could be explained by the fact that if (any) dopant substitutes TiO 2 in a bulk, it affects the presence of oxygen vacancies, lowering the temperature needed for the transformation from the anatase to rutile phase. [23][24][25] The (101) diffraction peak position was slightly shifted (≈0.04°) toward a lower angle, which might imply substitution of the larger ionic cations of both Li and Co at the Ti site and/or lattice distortion (see the inset plot of Figure 1d). Photographs of the TiO 2 powder with and without Li/Co treatment after annealing at 500 and 1000 °C are depicted in Figure S1 of the Supporting Information.…”

Section: Resultsmentioning

confidence: 99%

Combined Experimental and Simulation Studies of Lithium and Cobalt‐Modified TiO₂ and Their Impacts on the Performance and Stability of Perovskite Solar Cells

Smerchit

Thongprong

Ruengsrisang

et al. 2022

Adv Materials Inter

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Posttreatment of titanium oxide (TiO 2 ) using lithium (Li) and cobalt (Co) precursors is widely adopted to modify the charge quenching property in perovskite solar cells (PSCs); however, the fundamental understanding of the effect of the modification layer on the material itself and, consequently, the photovoltaic performance stability is not complete. In this work, in situ X-ray diffraction measurements show that the Li and Co ions can diffuse into TiO 2 and consequently accelerate the rutile phase transformation. X-ray photoelectron spectroscopy results reveal the appearance of a Ti 3+ feature in both the Li-and Co-treated samples, suggesting that the treatment ions are partially located at the subsurface/surface of the spin-cast TiO 2 layer. The Li-treated TiO 2 exhibits greatly upshifted conduction band edges, which benefits charge extraction properties and improves the average device parameters in a complete PSC. To complement the experiments, density functional theory calculations are performed. While Li treatment initially results in enhanced electronic properties, Li-treated TiO 2 tends to have more surface vacancies over time and is more susceptible to adsorption and accumulation of iodide ions compared to the Co-treated sample, which is experimentally supported by surface photovoltage spectroscopy and timeresolved photoluminescence results.

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Kinetic Study on the Crystal Transformation of Fe-Doped TiO₂ via In Situ High-Temperature X-ray Diffraction and Transmission Electron Microscopy

Cited by 10 publications

References 28 publications

Phase transition of individual anatase TiO₂ microcrystals with large percentage of (001) facets: a Raman mapping and SEM study

Phase transition of individual anatase TiO₂ microcrystals with large percentage of (001) facets: a Raman mapping and SEM study

New Insights into Crystal Defects, Oxygen Vacancies, and Phase Transition of Ir-TiO₂

Combined Experimental and Simulation Studies of Lithium and Cobalt‐Modified TiO₂ and Their Impacts on the Performance and Stability of Perovskite Solar Cells

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Kinetic Study on the Crystal Transformation of Fe-Doped TiO2 via In Situ High-Temperature X-ray Diffraction and Transmission Electron Microscopy

Cited by 10 publications

References 28 publications

Phase transition of individual anatase TiO2 microcrystals with large percentage of (001) facets: a Raman mapping and SEM study

Phase transition of individual anatase TiO2 microcrystals with large percentage of (001) facets: a Raman mapping and SEM study

New Insights into Crystal Defects, Oxygen Vacancies, and Phase Transition of Ir-TiO2

Combined Experimental and Simulation Studies of Lithium and Cobalt‐Modified TiO2 and Their Impacts on the Performance and Stability of Perovskite Solar Cells

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Kinetic Study on the Crystal Transformation of Fe-Doped TiO₂ via In Situ High-Temperature X-ray Diffraction and Transmission Electron Microscopy

Phase transition of individual anatase TiO₂ microcrystals with large percentage of (001) facets: a Raman mapping and SEM study

Phase transition of individual anatase TiO₂ microcrystals with large percentage of (001) facets: a Raman mapping and SEM study

New Insights into Crystal Defects, Oxygen Vacancies, and Phase Transition of Ir-TiO₂

Combined Experimental and Simulation Studies of Lithium and Cobalt‐Modified TiO₂ and Their Impacts on the Performance and Stability of Perovskite Solar Cells