Dye-sensitized Er^(3+)-doped CaF_(2)nanoparticles for enhanced near-infrared emission at 1.5μm  

作　　者：JING LIU FLAVIA ARTIZZU MIN ZENG LUCA PILIA PIETER GEIREGAT RIK VAN DEUN 

机构地区：[1]Key Laboratory of Luminescence Analysis and Molecular Sensing,Ministry of Education,School of Materials and Energy,Southwest University,Chongqing 400715,China [2]Department of Chemistry,Ghent University,B-9000 Ghent,Belgium [3]Department of Sciences and Technological Innovation,University of Eastern Piedmont“Amedeo Avogadro”,15121 Alessandria,Italy [4]Department of Mechanical,Chemical and Material Engineering,University of Cagliari,09123 Cagliari,Italy

出　　处：《Photonics Research》2021年第10期2037-2045,共9页光子学研究（英文版）

基　　金：National Natural Science Foundation of China(52002336);Fundamental Research Funds for the Central Universities(SWU019041);Science and Technology Project of Chongqing Education Committee(KJCX2020005);open project of State Key Laboratory of Marine Resource Utilization in South China Sea(MRUKF20210330);Research Foundation-Flanders(12U3417NLV).

摘　　要：Lanthanide(Ln)-doped nanoparticles have shown potential for applications in various fields.However,the weak and narrow absorption bands of the Ln ions(Ln^(3+)),hamper efficient optical pumping and severely limit the emission intensity.Dye sensitization is a promising way to boost the near-infrared(NIR)emission of Er^(3+),hence promoting possible application in optical amplification at 1.5μm,a region that is much sought after for telecommunication technology.Herein,we introduce the fluorescein isothiocyanate(FITC)organic dye with large absorption cross section as energy donor of small-sized(∼3.6 nm)Er^(3+)-doped CaF_(2)nanoparticles.FITC molecules on the surface of CaF_(2)work as antennas to efficiently absorb light,and provide the indirect sensitization of Er^(3+)boosting its emission.In this paper,we employ photoluminescence and transient absorption spectroscopy,as well as density functional theory calculations,to provide an in-depth investigation of the FITC→Er^(3+)energy transfer process.We show that an energy transfer efficiency of over 89%is achieved in CaF_(2):Er^(3+)@FITC nanoparticles resulting in a 28 times enhancement of the Er^(3+)NIR emission with respect to bare CaF_(2):Er^(3+).Through the multidisciplinary approach used in our work,we are able to show that the reason for such high sensitization efficiency stems from the suitable size and geometry of the FITC dye with a localized transition dipole moment at a short distance from the surface of the nanoparticle.

关 键 词：process. ABSORPTION hence 

分 类 号：TB383.1[一般工业技术—材料科学与工程]