Corrigendum to “Luminescence properties and cell uptake analysis of Y2O3: Eu, Bi nanophosphors for bio-imaging applications" [J Mater Res Technol 10 (2021) 797–807, ISSN 2238-7854]

“…The emission strength produced from the samples containing Y 2 O 3 was found to be several times stronger than those of free yttrium samples. [ 12–14 ] As a result, Y 2 O 3 is confirmed to have a substantial influence on the structure of glass and helps to improve its quality. Finally, managing glass functionality requires an understanding of the correlation between structure and characteristics.…”

Effect of Y³⁺ on the structural and photoluminescence properties of yttrium‐doped sodium borate glass

“…The emission strength produced from the samples containing Y 2 O 3 was found to be several times stronger than those of free yttrium samples. [ 12–14 ] As a result, Y 2 O 3 is confirmed to have a substantial influence on the structure of glass and helps to improve its quality. Finally, managing glass functionality requires an understanding of the correlation between structure and characteristics.…”

Effect of Y³⁺ on the structural and photoluminescence properties of yttrium‐doped sodium borate glass

“…Hirata et al prepared Eu, Bi doped Y 2 O 3 NPs by the sol-gel method, and the doped elements also have uniform element distribution. 55 Solgel methods can also be used for the synthesis of highly complex systems. For example, Kim et al used ethylene diamine tetraacetic acid (EDTA)-citrate as a complexing agent to prepare the Ce 1Àx (TM, RE)O 2Àx catalyst.…”

Rare earth oxide based electrocatalysts: synthesis, properties and applications

“…17 Various nanomaterials have luminescence properties, such as some metals, 19 quantum dots, 9 silicon nanoparticles, 20 and nanophosphors. 21 Rare Earth (RE) nanophosphors have significant benets because of their low toxicity, photostability, large Stokes shis, sharp emission bands, and high luminescence quantum yields. 22 These nanomaterials typically comprise inorganic crystalline matrices doped with luminescent lanthanide cations (Ln 3+ ).…”

A bacterial cellulose-based LiSrVO₄:Eu³⁺ nanosensor platform for smartphone sensing of levodopa and dopamine: point-of-care diagnosis of Parkinson's disease