TiO2 Photocatalysis for the Transformation of Aromatic Water Pollutants into Fuels

Publikation: Beitrag in FachzeitschriftÜbersichtsarbeitForschungPeer-Review

Autoren

  • Osama Al-Madanat
  • Yamen AlSalka
  • Wegdan Ramadan
  • Detlef W. Bahnemann

Externe Organisationen

  • University of Mutah
  • Alexandria University
  • Staatliche Universität Sankt Petersburg
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Details

OriginalspracheEnglisch
Aufsatznummer317
Seitenumfang44
FachzeitschriftCatalysts
Jahrgang11
Ausgabenummer3
PublikationsstatusVeröffentlicht - 28 Feb. 2021

Abstract

The growing world energy consumption, with reliance on conventional energy sources and the associated environmental pollution, are considered the most serious threats faced by man-kind. Heterogeneous photocatalysis has become one of the most frequently investigated technolo-gies, due to its dual functionality, i.e., environmental remediation and converting solar energy into chemical energy, especially molecular hydrogen. H2 burns cleanly and has the highest gravimetric gross calorific value among all fuels. However, the use of a suitable electron donor, in what so-called “photocatalytic reforming”, is required to achieve acceptable efficiency. This oxidation half-reaction can be exploited to oxidize the dissolved organic pollutants, thus, simultaneously improving the water quality. Such pollutants would replace other potentially costly electron donors, achieving the dual-functionality purpose. Since the aromatic compounds are widely spread in the environment, they are considered attractive targets to apply this technology. In this review, different aspects are highlighted, including the employing of different polymorphs of pristine titanium dioxide as pho-tocatalysts in the photocatalytic processes, also improving the photocatalytic activity of TiO2 by loading different types of metal co-catalysts, especially platinum nanoparticles, and comparing the effect of various loading methods of such metal co-catalysts. Finally, the photocatalytic reforming of aromatic compounds employing TiO2-based semiconductors is presented.

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TiO2 Photocatalysis for the Transformation of Aromatic Water Pollutants into Fuels. / Al-Madanat, Osama; AlSalka, Yamen; Ramadan, Wegdan et al.
in: Catalysts, Jahrgang 11, Nr. 3, 317, 28.02.2021.

Publikation: Beitrag in FachzeitschriftÜbersichtsarbeitForschungPeer-Review

Al-Madanat, O, AlSalka, Y, Ramadan, W & Bahnemann, DW 2021, 'TiO2 Photocatalysis for the Transformation of Aromatic Water Pollutants into Fuels', Catalysts, Jg. 11, Nr. 3, 317. https://doi.org/10.3390/catal11030317
Al-Madanat, O., AlSalka, Y., Ramadan, W., & Bahnemann, D. W. (2021). TiO2 Photocatalysis for the Transformation of Aromatic Water Pollutants into Fuels. Catalysts, 11(3), Artikel 317. https://doi.org/10.3390/catal11030317
Al-Madanat O, AlSalka Y, Ramadan W, Bahnemann DW. TiO2 Photocatalysis for the Transformation of Aromatic Water Pollutants into Fuels. Catalysts. 2021 Feb 28;11(3):317. doi: 10.3390/catal11030317
Al-Madanat, Osama ; AlSalka, Yamen ; Ramadan, Wegdan et al. / TiO2 Photocatalysis for the Transformation of Aromatic Water Pollutants into Fuels. in: Catalysts. 2021 ; Jahrgang 11, Nr. 3.
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abstract = "The growing world energy consumption, with reliance on conventional energy sources and the associated environmental pollution, are considered the most serious threats faced by man-kind. Heterogeneous photocatalysis has become one of the most frequently investigated technolo-gies, due to its dual functionality, i.e., environmental remediation and converting solar energy into chemical energy, especially molecular hydrogen. H2 burns cleanly and has the highest gravimetric gross calorific value among all fuels. However, the use of a suitable electron donor, in what so-called “photocatalytic reforming”, is required to achieve acceptable efficiency. This oxidation half-reaction can be exploited to oxidize the dissolved organic pollutants, thus, simultaneously improving the water quality. Such pollutants would replace other potentially costly electron donors, achieving the dual-functionality purpose. Since the aromatic compounds are widely spread in the environment, they are considered attractive targets to apply this technology. In this review, different aspects are highlighted, including the employing of different polymorphs of pristine titanium dioxide as pho-tocatalysts in the photocatalytic processes, also improving the photocatalytic activity of TiO2 by loading different types of metal co-catalysts, especially platinum nanoparticles, and comparing the effect of various loading methods of such metal co-catalysts. Finally, the photocatalytic reforming of aromatic compounds employing TiO2-based semiconductors is presented.",
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T1 - TiO2 Photocatalysis for the Transformation of Aromatic Water Pollutants into Fuels

AU - Al-Madanat, Osama

AU - AlSalka, Yamen

AU - Ramadan, Wegdan

AU - Bahnemann, Detlef W.

N1 - Funding Information: This work was supported by the Federal Ministry of Education and Research, Germany (033RC 029D), and Saint-Petersburg State University via a research grant ID 32706707.

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N2 - The growing world energy consumption, with reliance on conventional energy sources and the associated environmental pollution, are considered the most serious threats faced by man-kind. Heterogeneous photocatalysis has become one of the most frequently investigated technolo-gies, due to its dual functionality, i.e., environmental remediation and converting solar energy into chemical energy, especially molecular hydrogen. H2 burns cleanly and has the highest gravimetric gross calorific value among all fuels. However, the use of a suitable electron donor, in what so-called “photocatalytic reforming”, is required to achieve acceptable efficiency. This oxidation half-reaction can be exploited to oxidize the dissolved organic pollutants, thus, simultaneously improving the water quality. Such pollutants would replace other potentially costly electron donors, achieving the dual-functionality purpose. Since the aromatic compounds are widely spread in the environment, they are considered attractive targets to apply this technology. In this review, different aspects are highlighted, including the employing of different polymorphs of pristine titanium dioxide as pho-tocatalysts in the photocatalytic processes, also improving the photocatalytic activity of TiO2 by loading different types of metal co-catalysts, especially platinum nanoparticles, and comparing the effect of various loading methods of such metal co-catalysts. Finally, the photocatalytic reforming of aromatic compounds employing TiO2-based semiconductors is presented.

AB - The growing world energy consumption, with reliance on conventional energy sources and the associated environmental pollution, are considered the most serious threats faced by man-kind. Heterogeneous photocatalysis has become one of the most frequently investigated technolo-gies, due to its dual functionality, i.e., environmental remediation and converting solar energy into chemical energy, especially molecular hydrogen. H2 burns cleanly and has the highest gravimetric gross calorific value among all fuels. However, the use of a suitable electron donor, in what so-called “photocatalytic reforming”, is required to achieve acceptable efficiency. This oxidation half-reaction can be exploited to oxidize the dissolved organic pollutants, thus, simultaneously improving the water quality. Such pollutants would replace other potentially costly electron donors, achieving the dual-functionality purpose. Since the aromatic compounds are widely spread in the environment, they are considered attractive targets to apply this technology. In this review, different aspects are highlighted, including the employing of different polymorphs of pristine titanium dioxide as pho-tocatalysts in the photocatalytic processes, also improving the photocatalytic activity of TiO2 by loading different types of metal co-catalysts, especially platinum nanoparticles, and comparing the effect of various loading methods of such metal co-catalysts. Finally, the photocatalytic reforming of aromatic compounds employing TiO2-based semiconductors is presented.

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