4(11), 1760–1766 (2016b)Ĭhen, B., Wu, M., Liu, Q., He, C., Yang, Y., Liu, Y., Yang, C., Wen, X., Min, X., Huang, Z.: Preparation and photoluminescence properties of CaSc2O4: Eu 3+ red phosphor for white LEDs. 25(34), 5462–5471 (2015)Ĭhen, G., Shao, W., Valiev, R.R., Ohulchanskyy, T.Y., He, G.S., Ågren, H., Prasad, P.N.: Efficient broadband upconversion of near-infrared light in dye-sensitized core/shell nanocrystals. 135, 23–32 (2014)Ĭhen, X., Xu, W., Zhang, L., Bai, X., Cui, S., Zhou, D., Yin, Z., Song, H., Kim, D.: Large upconversion enhancement in the “Islands” Au–Ag Alloy/NaYF 4: Yb 3+, Tm 3+/Er 3+ composite films, and fingerprint identification. Status Solidi B 148(1), 11–47 (1988)Ĭhen, Y., Liang, H.: Applications of quantum dots with upconverting luminescence in bioimaging. Keywordsīeery, D., Schmidt, T.W., Hanson, K.: Harnessing sunlight via molecular photon upconversion. In the last, optical applications of these materials for light-emitting diodes, display devices, optical temperature sensors, security, laser material, and optical-imaging applications have also been included. Different types of sensitization mechanisms for lanthanide luminescence along with the different types of energy transfer processes in them have also been discussed by taking different examples. Further, the downshifting and upconversion-based luminescence of lanthanide ions has been briefed in different types of host matrices including inorganic oxide phosphors, fluoride-based phosphors, organic complexes, metal oxide frameworks, halide perovskites, and composite materials. This chapter gives a brief account of lanthanides and the basics of luminescence in them. Lanthanide luminescence is widely used in different areas including spectroscopy, materials science, nanotechnology, chemistry, and bio-medical applications due to their unique optical emission.
0 Comments
Leave a Reply. |
AuthorWrite something about yourself. No need to be fancy, just an overview. ArchivesCategories |