Among several parameters that affect the yield of a photocatalytic process mediated by a metal oxide semiconductor, key is the efficient separation and transfer of photo-generated charge carriers. To overcome kinetic limitations and enable charge transfer, an effective strategy is to decorate the photocatalyst surface with cocatalytic nanoparticles of either a second semiconductor metal oxide or a noble metal. Nevertheless, classical deposition techniques based on powder technology approaches lead to randomly placed cocatalytic nanoparticles at the photocatalytic surface. The poor control over cocatalyst placement can drastically hamper the photocatalytic efficiencies, and can also prevent a full understanding of the charge carrier dynamics and photocatalytic mechanism. Here we investigate a highly defined charge separation platform for photocatalytic H2evolution based on a Pt-WO3-TiO2“stacked” structure constructed on anodically grown TiO2nanotube arrays. Key is the formation of a site-selective and sequential W and Pt metal sputter-decoration only at the mouth of highly-ordered TiO2nanotubes. After placing the W-Pt bilayer at the nanotubes mouth, a suitable thermal treatment forms a WO3layer atop the nanotubes while the Pt film undergoes solid state dewetting into 2–6 nm-sized Pt nanoparticles. These structures show strongly improved photocatalytic H2evolution efficiency compared to any other single-cocatalyst system (Pt-TiO2and WO3-TiO2) and pristine TiO2nanotubes. The photocatalytic activity improvement is ascribed to an enhanced charge carrier separation mechanism enabled by the well-defined TiO2-WO3-Pt architecture that provides swift electron transfer through WO3and towards Pt for H2evolution.

Site-selective Pt dewetting on WO3-coated TiO2nanotube arrays: An electron transfer cascade-based H2evolution photocatalyst

Spanu, Davide;Recchia, Sandro;
2018-01-01

Abstract

Among several parameters that affect the yield of a photocatalytic process mediated by a metal oxide semiconductor, key is the efficient separation and transfer of photo-generated charge carriers. To overcome kinetic limitations and enable charge transfer, an effective strategy is to decorate the photocatalyst surface with cocatalytic nanoparticles of either a second semiconductor metal oxide or a noble metal. Nevertheless, classical deposition techniques based on powder technology approaches lead to randomly placed cocatalytic nanoparticles at the photocatalytic surface. The poor control over cocatalyst placement can drastically hamper the photocatalytic efficiencies, and can also prevent a full understanding of the charge carrier dynamics and photocatalytic mechanism. Here we investigate a highly defined charge separation platform for photocatalytic H2evolution based on a Pt-WO3-TiO2“stacked” structure constructed on anodically grown TiO2nanotube arrays. Key is the formation of a site-selective and sequential W and Pt metal sputter-decoration only at the mouth of highly-ordered TiO2nanotubes. After placing the W-Pt bilayer at the nanotubes mouth, a suitable thermal treatment forms a WO3layer atop the nanotubes while the Pt film undergoes solid state dewetting into 2–6 nm-sized Pt nanoparticles. These structures show strongly improved photocatalytic H2evolution efficiency compared to any other single-cocatalyst system (Pt-TiO2and WO3-TiO2) and pristine TiO2nanotubes. The photocatalytic activity improvement is ascribed to an enhanced charge carrier separation mechanism enabled by the well-defined TiO2-WO3-Pt architecture that provides swift electron transfer through WO3and towards Pt for H2evolution.
2018
www.elsevier.com/inca/publications/store/5/2/3/0/6/6/index.htt
Anodic TiO2nanotubes; Charge transfer; Electron transfer cascade; Photocatalytic H2generation; Pt dewetting; WO3; Catalysis; 2300; Process Chemistry and Technology
Spanu, Davide; Recchia, Sandro; Mohajernia, Shiva; Schmuki, Patrik; Altomare, Marco
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11383/2073248
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