Synergistic Effect of Cu,F‐Codoping of Titanium Dioxide for Multifunctional Catalytic and Photocatalytic Studies

Abstract: This material has been used as a photo catalyst for water splitting since 1972 when Fujishima and Honda reported its ability to generate hydrogen and oxygen from water molecules. [1] Titanium dioxide is normally used in advanced oxidation processes, [2] in systems capable of elimi nating a wide variety of chemicals in air and water, as well as solar fuel production (such as H 2 ). [3,4] The photoactivated pro cesses of titanium dioxidebased photo catalysts are achieved when the irradiation energy is higher t… Show more

“…S7 of the ESI †), one can observe that the F-doped material does not show peaks corresponding to brookite, promoting the formation of a material composed mainly of the anatase phase. Therefore, as confirmed previously for analogous systems, 25,26 F-doping inhibits the formation of brookite. Even though the calcinations at temperatures higher than 550 °C favour the transition to rutile, 25,26,40 in the case of F-TiO 2 -NA-500 with a calcination temperature below 550 °C, the anatase phase seems to be the unique crystalline phase.…”

“…Therefore, as confirmed previously for analogous systems, 25,26 F-doping inhibits the formation of brookite. Even though the calcinations at temperatures higher than 550 °C favour the transition to rutile, 25,26,40 in the case of F-TiO 2 -NA-500 with a calcination temperature below 550 °C, the anatase phase seems to be the unique crystalline phase. Furthermore, the presence of fluorine lowers the crystallite size when compared with the non-doped material TiO 2 -NA-500, which is related to the presence of Ti 3+ centres.…”

“…It seems that F-doping is associated with a growth in the porosity of the system, as previously reported by our group 25,72 and with an increase in the pore diameter (D p ) and pore volume (V p ), compared with its non-doped analogue. This fact is in agreement with the photocatalytic results which show a higher photodegradation activity in F-doped systems.…”

“…In addition, our interest is also focused on preparing F-doped TiO 2 materials as these preferentially form ultrareactive {001} facets [20][21][22] and exhibit optimal structural properties for applications in photocatalysis. [23][24][25][26] Suzuki-Miyaura and similar cross-coupling reactions (Heck, Buchwald-Hartwig, etc.) are versatile tools for specific organic syntheses in both academic and industrial contexts.…”

“…[33][34][35] Usually, these supports play only a structural role in the catalytic process, although there are occasions in which their role is also crucial. 25 The active metal-support strength has a significant effect on catalyst performance. Depending on the material used, it can influence the electronic environment of the active sites, affecting their morphology and activity.…”

Modulation of the photocatalytic activity and crystallinity of F-TiO₂ nanoparticles by using green natural carboxylic acids

“…S7 of the ESI †), one can observe that the F-doped material does not show peaks corresponding to brookite, promoting the formation of a material composed mainly of the anatase phase. Therefore, as confirmed previously for analogous systems, 25,26 F-doping inhibits the formation of brookite. Even though the calcinations at temperatures higher than 550 °C favour the transition to rutile, 25,26,40 in the case of F-TiO 2 -NA-500 with a calcination temperature below 550 °C, the anatase phase seems to be the unique crystalline phase.…”

“…Therefore, as confirmed previously for analogous systems, 25,26 F-doping inhibits the formation of brookite. Even though the calcinations at temperatures higher than 550 °C favour the transition to rutile, 25,26,40 in the case of F-TiO 2 -NA-500 with a calcination temperature below 550 °C, the anatase phase seems to be the unique crystalline phase. Furthermore, the presence of fluorine lowers the crystallite size when compared with the non-doped material TiO 2 -NA-500, which is related to the presence of Ti 3+ centres.…”

“…It seems that F-doping is associated with a growth in the porosity of the system, as previously reported by our group 25,72 and with an increase in the pore diameter (D p ) and pore volume (V p ), compared with its non-doped analogue. This fact is in agreement with the photocatalytic results which show a higher photodegradation activity in F-doped systems.…”

“…In addition, our interest is also focused on preparing F-doped TiO 2 materials as these preferentially form ultrareactive {001} facets [20][21][22] and exhibit optimal structural properties for applications in photocatalysis. [23][24][25][26] Suzuki-Miyaura and similar cross-coupling reactions (Heck, Buchwald-Hartwig, etc.) are versatile tools for specific organic syntheses in both academic and industrial contexts.…”

“…[33][34][35] Usually, these supports play only a structural role in the catalytic process, although there are occasions in which their role is also crucial. 25 The active metal-support strength has a significant effect on catalyst performance. Depending on the material used, it can influence the electronic environment of the active sites, affecting their morphology and activity.…”

Modulation of the photocatalytic activity and crystallinity of F-TiO₂ nanoparticles by using green natural carboxylic acids

Delocalized Electrons via In Situ CNT Growth on Au/g‐C₃N₄ for Boosting Photocatalytic H₂ Evolution

Direct and Indirect Effects of Fluorine on the Photocatalytic Performance of Titania‐Based Photocatalysts