LuVO4:Eu3+ nanorods: synthesis and luminescence

“…11e). 82 Professor Zhang and colleagues 83 synthesized a keto anthraquinone COF via mechanochemical synthesis, achieving a remarkable H 2 O 2 yield of 4784 μmol g −1 h −1 under visible light conditions exceeding 400 nm. The keto anthraquinone structure facilitates the adsorption of OH − (H 2 O) n from water clusters, while its OH − dissociative structure effectively reduces the hydrogen energy barrier of water molecules.…”

Advancements in controlling COFs structure for enhanced crystallization properties and self-generated photocatalytic hydrogen peroxide

“…11e). 82 Professor Zhang and colleagues 83 synthesized a keto anthraquinone COF via mechanochemical synthesis, achieving a remarkable H 2 O 2 yield of 4784 μmol g −1 h −1 under visible light conditions exceeding 400 nm. The keto anthraquinone structure facilitates the adsorption of OH − (H 2 O) n from water clusters, while its OH − dissociative structure effectively reduces the hydrogen energy barrier of water molecules.…”

Advancements in controlling COFs structure for enhanced crystallization properties and self-generated photocatalytic hydrogen peroxide

“…Most luminescent materials are usually oxides, sulfides, or oxysulfides doped with some transition metal or rare-earth element [6][7][8], but in recent years, some lanthanides known as orthovanadates are currently used as matrices due to their high emission efficiency [9][10][11][12]. Additionally, these materials have unique properties due to the stoichiometric combination of their components and their symmetry with the crystal of the complex oxides; these characteristics increase the luminescent activity in comparison with the simple materials [13][14][15][16][17][18]. Likewise, rare-earth ions that are used as impurities in orthovanadates have shown strong emissions as well as variations in the emission color corresponding to the different activating ions under the excitation of an electron beam or ultraviolet.…”

Luminescence Properties and Energy Transfer of Eu3+, Bi3+ Co-Doped LuVO4 Films Modified with Pluronic F-127 Obtained by Sol–Gel

Ca2MgSi2O7:Ce3+/Tb3+/Eu3+ phosphors: Multicolor tunable luminescence via Ce3+ → Tb3+, Tb3+ → Eu3+ and Ce3+ → Tb3+ → Eu3+ energy transfers