Enhancement of Upconversion Luminescence through Three-Dimensional Design of Plasma Ti 3 O 5 -Coupled Structural Domain-Limiting Effects.
Jing XuYusheng XuJun YanYuting WuYuheng ZhangYong YangDacheng ZhouZhangwen LongQi WangJian-Bei QiuPublished in: ACS applied materials & interfaces (2024)
Upconversion luminescence plays a crucial role in various technological applications, and among the various valence states of lanthanide elements, Ln 3+ has the highest stability. The 4f orbitals of these elements are in a fully empty, semifull, or full state. This special 4f electron configuration allows them to exhibit rich discrete energy levels. However, the 4f-4f transition of Ln 3+ rare earth ions itself is prohibited, resulting in a lower luminescence efficiency. This limitation greatly hinders the practical application of upconversion luminescence. In this study, we report nanostructured luminescence-enhanced substrate platforms with both semiconductive local surface plasmons and spatially confined domain effects on a single defect semiconductor substrate. By coupling NaYF 4 :Yb-Er nanoparticle emitters to the surface of Ti 3 O 5 NC-arrays plasmonic nanostructures, an ultrabright luminescence with a 32-fold increase in green emission and a 40-fold increase in red emission was achieved. Furthermore, the fluorescence resonance energy transfer characteristics observed in the R6G/NaYF 4 /Ti 3 O 5 NC-array composite film enable accurate detection of fluorescent molecules. The results provide an innovative and intelligent approach to enhance the upconversion luminescence intensity of rare-doped nanoparticles and develop highly sensitive molecular detection systems based on the above luminescence enhancement.