Such https://www.selleckchem.com/products/napabucasin.html a drastic reduction in the crystallization time allows the specific surface area and the porosity to retain high values, eventually leading to a better photocatalytic performance: as shown in Figure 5, when the as-synthesized TiO2 spheres are subjected to 10 to 15 min of MW sintering; the methyl orange is almost completely photodegraded after 6 h, this result being remotely accessible for a conventionally sintered powder. Figure 5 Evolution of methyl orange concentration during the photocatalytic test. Conclusions
When conventional electric heating is applied to consolidate an amorphous powder of hierarchically nanostructured anatase microspheres, an increase in the crystal order is inescapably accompanied by a deleterious decrease in the specific surface and the porosity which dramatically reduces the photoactivity of
this TiO2-based material. To avoid this scenario, microwave sintering has been successfully see more applied as an eco-friendly (energy saving) consolidation alternative: by reducing the heating time to just a few minutes, microwave radiation promotes the fast crystallization of the nanostructured microspheres, allowing the starting anatase powder to achieve a high crystallinity while keeping a high specific surface area and low density. As a straight consequence, the hunting of photons, the absorption of guest species and the photo-induced charge separation is fostered, eventually harvesting an improved photocatalytic performance. Acknowledgements This work was supported by the Spanish Ministry of Economy and Competitiveness (MINECO) through the projects IPT-120000-2010-033 (GESHTOS), IPT-2011-1113-310000 (NANOBAC), CICYTMAT
2010-16614, MAT2010-18432 and CSD2008-00023. Dr T. Jardiel also acknowledges the JAE-Doc contract of the Spanish National Research Council (CSIC) and the European Science Foundation (ESF). Dr M. Peiteado acknowledges the Ramon y Cajal Program of MINECO for the financial support. References 1. Grätzel M: Photochemical cells. Nature 2001, 414:338–344.CrossRef 2. Wang D, Choi D, Li J, Yang Z, Nie Z, Kou R, Hu D, Wang C, Saraf LV, Zhang J, Aksay IA, Liu J: Self-assembled TiO2-graphene hybrid nanostructures Methocarbamol for enhanced Li-ion insertion. ACS Nano 2009, 3:907–914.CrossRef 3. Kim DH, Seong WM, Park IJ, Yoo E-S, Shin SS, Kim JS, Jung HS, Lee S, Hong KS: Anatase TiO2 nanorod-decoration for highly efficient photoenergy conversion. Nanoscale 2013, 5:11725–11732.CrossRef 4. Hu X, Li G, Yu JC: Design, fabrication, and modification of nanostructured semiconductor materials for environmental and energy applications. Langmuir 2010, 26:3031–3039.CrossRef 5. Calatayud DG, Jardiel T, Peiteado M, Rodríguez CF, Selleck CFTRinh-172 Espino Estévez MR, Doña Rodríguez JM, Palomares FJ, Rubio F, Fernández-Hevia D, Caballero AC: Highly photoactive anatase nanoparticles obtained using trifluoroacetic acid as an electron scavenger and morphological control agent. J Mater Chem A 2013, 1:14358.