Doping of TiO<sub>2</sub>for sensitized solar cells

Roose, Bart; Pathak, Sandeep; Steiner, Ullrich

doi:10.1039/c5cs00352k

Cited by 390 publications

(265 citation statements)

References 285 publications

(453 reference statements)

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“…The degradation of PSCs has been ascribed to several different mechanisms related to the metal oxide component, the main ones being UV-light induced desorption of O 2 from the metal oxide surface 17,18 and the photocatalytic properties of TiO 2 actively degrading the perovskite light absorber. 19,34 Aer storing the devices in the dark for 200 hours, the PCE does not recover. As O 2 desorption is reversible, this process can be excluded, leaving the photocatalytic degradation catalyzed by the metal oxide as the most likely degradation pathway.…”

Section: à2mentioning

confidence: 99%

“…Doping metal oxides can have large effects on the morphology of the electrode 34 and doping can thus affect the metal oxide-perovskite interface area and penetration of the perovskite into the mesoporous metal oxide network. To minimise the inuence of morphology on device performance, the self-assembly of the amphiphilic block-copolymer polyisopreneblock-polyethylene oxide (PI-b-PEO) was used to direct the mSnO 2 morphology.…”

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confidence: 99%

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A Ga-doped SnO₂ mesoporous contact for UV stable highly efficient perovskite solar cells

et al. 2018

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Increasing the stability of perovskite solar cells is a major challenge for commercialization. The highest efficiencies so far have been achieved in perovskite solar cells employing mesoporous TiO 2 (m-TiO 2 ).One of the major causes of performance loss in these m-TiO 2 -based perovskite solar cells is induced by UV-radiation. This UV instability can be solved by replacing TiO 2 with SnO 2 ; thus developing a mesoporous SnO 2 (m-SnO 2 ) perovskite solar cell is a promising approach to maximise efficiency and stability. However, the performance of mesoporous SnO 2 (m-SnO 2 ) perovskite solar cells has so far not been able to rival the performance of TiO 2 based perovskite solar cells. In this study, for the first time, high-efficiency m-SnO 2 perovskite solar cells are fabricated, by doping SnO 2 with gallium, yielding devices that can compete with TiO 2 based devices in terms of performance. We found that gallium doping severely decreases the trap state density in SnO 2 , leading to a lower recombination rate. This, in turn, leads to an increased open circuit potential and fill factor, yielding a stabilised power conversion efficiency of 16.4%. The importance of high-efficiency m-SnO 2 based perovskite solar cells is underlined by stability data, showing a marked increase in stability under full solar spectrum illumination.

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Section: à2mentioning

confidence: 99%

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A Ga-doped SnO₂ mesoporous contact for UV stable highly efficient perovskite solar cells

et al. 2018

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“…Such physico-chemical properties promote the use of TiO 2 mostly as photocatalyst and/or a catalytic support [3][4][5][6][7], although it is also used in dye sensitized solar cells [8][9][10][11] and, recently, in biomedical applications [12,13]. Moreover, the possibility of obtaining ordered porous structures with remarkable specific surface area (SSA) enhances the use of TiO 2 in…”

Section: Introductionmentioning

confidence: 99%

Pure and Fe-Doped Mesoporous Titania Catalyse the Oxidation of Acid Orange 7 by H2O2 under Different Illumination Conditions: Fe Doping Improves Photocatalytic Activity under Simulated Solar Light

et al. 2017

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A sample of mesoporous TiO 2 (MT, specific surface area = 150 m 2 ·g −1 ) and two samples of MT containing 2.5 wt.% Fe were prepared by either direct synthesis doping (Fe2.5-MTd) or impregnation (Fe2.5-MTi). Commercial TiO 2 (Degussa P25, specific surface area = 56 m 2 ·g −1 ) was used both as a benchmark and as a support for impregnation with either 0.8 or 2.5 wt.% Fe (Fe0.80-IT and Fe2.5-IT). The powders were characterized by X-ray diffraction, N 2 isotherms at −196 • C, Energy Dispersive X-ray (EDX) Spectroscopy, X-ray Photoelectron Spectroscopy (XPS), Diffuse Reflectance (DR) ultra-violet (UV)-Vis and Mössbauer spectroscopies. Degradation of Acid Orange 7 (AO7) by H 2 O 2 was the test reaction: effects of dark-conditions versus both UV and simulated solar light irradiation were considered. In dark conditions, AO7 conversion was higher with MT than with Degussa P25, whereas Fe-containing samples were active in a (slow) Fenton-like reaction. Under UV light, MT was as active as Degussa P25, and Fe doping enhanced the photocatalytic activity of Fe2.5-MTd; Fe-impregnated samples were also active, likely due to the occurrence of a photo-Fenton process. Interestingly, the Fe2.5-MTd sample showed the best performance under solar light, confirming the positive effect of Fe doping by direct synthesis with respect to impregnation.

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“…The applicative potential of TiO 2 -photocatalysis is presently focused on the areas such as environmental remediation (water treatment [2][3][4] and air purification [5]), renewable energy processes-water splitting for hydrogen production [6], conversion of CO 2 to hydrocarbons [7], solar cells [8]-and self-cleaning surfaces [9]. TiO 2 is characterized by those properties that are indispensable to fulfill the requirements of efficient, stable, and green photocatalytic material (long term stability, chemical inertness, corrosion resistance, non-toxicity) [1].…”

Section: Introductionmentioning

confidence: 99%

On the Origin of Enhanced Photocatalytic Activity of Copper-Modified Titania in the Oxidative Reaction Systems

2017

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Modification of titania with copper is a promising way to enhance the photocatalytic performance of TiO 2 . The enhancement means the significant retardation of charge carriers' recombination ratio and the introduction of visible light activity. This review focuses on two main ways of performance enhancement by copper species-i.e., originated from plasmonic properties of zero-valent copper (plasmonic photocatalysis) and heterojunctions between semiconductors (titania and copper oxides). The photocatalytic performance of copper-modified titania is discussed for oxidative reaction systems due to their importance for prospective applications in environmental purification. The review consists of the correlation between copper species and corresponding variants of photocatalytic mechanisms including novel systems of cascade heterojunctions. The problem of stability of copper species on titania, and the methods of its improvement are also discussed as important factors for future applications. As a new trend in the preparation of copper-modified titania photocatalyst, the role of particle morphology (faceted particles, core-shell structures) is also described. Finally, in the conclusion section, perspectives, challenges and recommendations for future research on copper-modified titania are formulated.

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Doping of TiO₂for sensitized solar cells

Cited by 390 publications

References 285 publications

A Ga-doped SnO₂ mesoporous contact for UV stable highly efficient perovskite solar cells

A Ga-doped SnO₂ mesoporous contact for UV stable highly efficient perovskite solar cells

Pure and Fe-Doped Mesoporous Titania Catalyse the Oxidation of Acid Orange 7 by H2O2 under Different Illumination Conditions: Fe Doping Improves Photocatalytic Activity under Simulated Solar Light

On the Origin of Enhanced Photocatalytic Activity of Copper-Modified Titania in the Oxidative Reaction Systems

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Doping of TiO2for sensitized solar cells

Cited by 390 publications

References 285 publications

A Ga-doped SnO2 mesoporous contact for UV stable highly efficient perovskite solar cells

A Ga-doped SnO2 mesoporous contact for UV stable highly efficient perovskite solar cells

Pure and Fe-Doped Mesoporous Titania Catalyse the Oxidation of Acid Orange 7 by H2O2 under Different Illumination Conditions: Fe Doping Improves Photocatalytic Activity under Simulated Solar Light

On the Origin of Enhanced Photocatalytic Activity of Copper-Modified Titania in the Oxidative Reaction Systems

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Doping of TiO₂for sensitized solar cells

A Ga-doped SnO₂ mesoporous contact for UV stable highly efficient perovskite solar cells

A Ga-doped SnO₂ mesoporous contact for UV stable highly efficient perovskite solar cells