Overcoming Pd–TiO₂ Deactivation during H₂ Production from Photoreforming Using Cu@Pd Nanoparticles Supported on TiO₂

Abstract: Different Cu@Pd–TiO2 systems have been prepared by a two-step synthesis to obtain a bimetallic co-catalyst for the H2 photoreforming reaction. We find that the tailored deposition of Pd covering the Cu nanoclusters by a galvanic replacement process results in the formation of a core@shell structure. The photocatalytic H2 production after 18 h is 350 mmol/g on the Cu@Pd1.0–TiO2 bimetallic system, which is higher than that on the monometallic ones with a H2 production of 250 mmol/g on Pd-supported TiO2. Surface … Show more

“…Based on this, it can be proposed that Pd/TiO 2– x possesses a more robust SMSI effect compared with Pd/TiO 2 catalyst. Peaks within the 450–550 °C range are the reduction of stable PdO with strong interaction with TiO 2 support, or PdO with high dispersion on TiO 2 or the Pd 2+ –V O –Ti 3+ complex. ,, The reduction of the Pd 2+ –V O –Ti 3+ complex occurs at 490 and 500 °C for the Pd/TiO 2– x and Pd/TiO 2 catalysts, respectively. Herein, the dispersion of the supported Pd species on these two catalysts cannot yet be inferred based solely on this peak, since this high temperature (higher than 450 °C at which the catalysts were prepared) itself can cause both sintering and the SMSI effect for the dispersed Pd metals.…”

Pd Nanoparticles Supported on N-Doped TiO₂ Nanosheets: Crystal Facets, Defective Sites, and Metal–Support Interactions Boost Reforming of Formaldehyde Solution for Hydrogen Production

“…Based on this, it can be proposed that Pd/TiO 2– x possesses a more robust SMSI effect compared with Pd/TiO 2 catalyst. Peaks within the 450–550 °C range are the reduction of stable PdO with strong interaction with TiO 2 support, or PdO with high dispersion on TiO 2 or the Pd 2+ –V O –Ti 3+ complex. ,, The reduction of the Pd 2+ –V O –Ti 3+ complex occurs at 490 and 500 °C for the Pd/TiO 2– x and Pd/TiO 2 catalysts, respectively. Herein, the dispersion of the supported Pd species on these two catalysts cannot yet be inferred based solely on this peak, since this high temperature (higher than 450 °C at which the catalysts were prepared) itself can cause both sintering and the SMSI effect for the dispersed Pd metals.…”

Pd Nanoparticles Supported on N-Doped TiO₂ Nanosheets: Crystal Facets, Defective Sites, and Metal–Support Interactions Boost Reforming of Formaldehyde Solution for Hydrogen Production

“…As was shown in the P25-based catalysts, the fact that no saturation in hydrogen production was observed indicates that an increase in MoS 2 loading could lead to even higher hydrogen productions than those observed. When irradiated with visible light (λ > 400 nm), the electrons of the AgNPs are excited due to the plasmon resonance and injected into the CB of the TiO 2 [17], producing holes in the AgNPs that serve as oxidation agents that could lead to oxygen production or to their being quenched by a sacrificial electron donor [25]. The electrons that were injected to the conduction band of TiO 2 are gained by the water molecules, and hydrogen is produced.…”

“…As a solution to this problem, TiO 2 can be synthesized in different crystalline structures and forms and modified by adding noble metals to reduce the band gap and optimize the use of sunlight [7]. The incorporation of silver (Ag) nanoparticles on the surface of TiO 2 makes it possible to change the properties of the semiconductor and diminish the rapid recombination of the photogenerated charge carriers in the process, shifting the radiation absorption threshold to the visible region [17]. The reason for this behavior is the surface plasmon resonance effect and charge separation by the displacement of photoexcited electrons from the metal nanoparticles to the conduction band (CB) of TiO 2 [17].…”

“…The incorporation of silver (Ag) nanoparticles on the surface of TiO 2 makes it possible to change the properties of the semiconductor and diminish the rapid recombination of the photogenerated charge carriers in the process, shifting the radiation absorption threshold to the visible region [17]. The reason for this behavior is the surface plasmon resonance effect and charge separation by the displacement of photoexcited electrons from the metal nanoparticles to the conduction band (CB) of TiO 2 [17]. Molybdenum disulfide (MoS 2 ) is considered a promising HER catalyst due to its high catalytic activity, high abundance, and low cost [6,12,18].…”

Hydrogen Production and Degradation of Ciprofloxacin by Ag@TiO2-MoS2 Photocatalysts

“…Many researchers have reported that noble metal NPs, such as Au, Pt, Ag, Rh, Ni-Pt, Pd, Cu-Pd, and Au-Pd have been reported resulting in enhanced overall photocatalytic activity by enhancing the electron-hole charge separation. [61][62][63][64][65][66][67][68][69][70][71] In this regard, SnS 2 nanostructures were synthesized by hydrothermal method and were in situ decorated with Ni as a cocatalyst having different concentrations of Ni i.e., 1 mol%, 2.5 mol%, 5 mol%, and 10 mol% through a simple thermal reduction method. The detailed physico-chemical characterisation and inuence of Ni loading on SnS 2 towards its photocatalytic performance were investigated.…”

Ni loaded SnS₂ hexagonal nanosheets for photocatalytic hydrogen generation via water splitting