| Lanthanide-doped up-conversion nanoparticles can convert near-infrared light into ultraviolet and visible light emission,showing advantages of large anti-Stokes shift,sharp emission peak,low toxicity and high chemical stability,which provide a solid foundation for their biological and photonic applications,such as bioimaging,anti-counterfeiting safety,super-resolution imaging,laser and photodynamic therapy.In order to meet the different needs in practical applications,it is necessary to control optical properties of up-conversion materials.The physical mechanism of lanthanide ion doped upconversion on the nanoscale was deeply studied.Despite the progress,there are many unresolved fundamental problems which hinder the in-depth understanding of rare earth upconversion kinetics,such as the small extinction coefficient of rare earth ions,the weak excitation light absorption of up-conversion nanoparticles,and concentration quenching at high doping concentrations.In addition,the energy mechanisms of rare earth ions for some processes are still unclear,the various crystal structures and morphologies are lacking.Recent research suggested that Yb3+has new functions instead of being a sensitizer in the up-conversion system,such as the tuning of the emission colors and lifetimes.In addition,the design of nanostructure with special structures would be of great significance for the fine spectral control and luminescence dynamics of upconversion systems.To further study these obstructions,in this thesis,the upconversion spectral properties,the physical mechanism of Yb3+energy transfer in the up-conversion nano-system and the energy transfer and energy migration effect of the lanthanide rare earth fluoride were systematically study.Moreover,the crystal structural evolution mechanism of"flower-like"nanoparticles was fully explored,which provides important reference information for the synthesis of nanomaterials.Up-conversion nanoparticle with orthogonal emission response controlled by an excitation light source was further developed.The main research contents of this thesis are listed as follows:(1)The role of Yb in optical properties of the Nd/Yb coupled up-conversion system under 808 nm excitation,and an in-depth understanding of the role of Yb3+in this coupled system.By adjusting the concentration of Yb3+in the middle layer of NaYF4:Yb/Er@NaYF4:Yb@NaYF4:Nd/Yb nanoparticles,the energy transfer effect on the Yb3+sublattice has been studied to promote the transmission process of sensitizer to activator,and improve up-conversion luminous intensity.At the same time,the physical mechanism of Yb3+energy transfer on the Nd3+sub-lattice is analyzed.According to the energy transfer properties of Yb-A(A=Er,Tm,Ho),the interface energy transfer process of Yb3+at the interface is further studied.By designing NaYF4:Er@NaYF4:Yb nanoparticles,it is explored that the interface energy transfer enhances the upconversion emission process of Er.By using infrared dye ICG molecules to further sensitize the nanoparticles,the upconversion luminescence intensity is significantly enhanced.These research contents provide in-depth understanding of the mechanism of energy transfer interaction in lanthanides.(2)The self-sensitized up-conversion luminescence phenomenon of highly doped Nd3+has been systematically studied.We designed a NaGd F4@NaGd F4:Yb/Nd@NaGd F4nanostructure,sandwiching the active light-emitting layer between inert layers to reduce the loss of energy transfer in space and the effect of surface quenching.It is found that highly doped Yb3+can well mediate and utilize the excitation energy in the energy cycle of Nd3+?Yb3+?Nd3+,resulting in a significant increase in the content of Nd3+,thereby effectively avoiding concentration quenching.Nd3+586 nm upconversion emission at 2G7/2 energy level can be enhanced by two orders of magnitude.By analyzing the results of downshift spectra under 808 nm excitation,it was determined that the effective energy transfer of Nd?Yb is the key to the effective visible upconversion emission of Nd3+.The phonon assisted energy transfer of Yb?Nd under the excitation of 980 nm is studied,and the process of phonon assisted energy transfer is sensitive to temperature,so we carried out temperature detection and analysis on the sample and found that the sample showed a trend of thermal enhancement with increasing temperature.This system has a good application prospect in the field of optical sensing,and the temperature probe within 303-393 K has been successfully prepared,and the maximum absolute sensitivity at 303 K is 3.6 K-1.(3)The influence of the Yb3+migration layer on the upconversion emission of the highly doped Er3+system was systematically studied.In the upconversion test under 980 nm excitation,the thickness of the Yb3+migration layer in NaEr F4:Yb/Tm@NaYF4:Yb nanoparticles was adjusted,and it was found that the thickness of the migration layer can change the emission of Er3+from red to green emission.By designing appropriate reaction conditions,adjusting the reaction temperature,the amount of rare earth ions,and the amount of shell precursors,we have developed a general method for synthesizing uniform morphology and hexagonal"flower-like"nanoparticles.Based on the incomplete coating of flower-like nanoparticles,and by further fine-tuning and controlling the energy transfer path betweenthesensitizerandactivatorions,wesynthesized NaEr F4:Yb/Tm@NaYF4:Yb@NaGd F4:Yb/Nd flower-like nanoparticles,the sample will adjust the different energy levels of the same activator ion along a specific path at a specific excitation wavelength,with different emission wavelengths under excitation at 808 nm,980nm,and 1530 nm,and very sensitive to 980 nm excitation power,just change the power range from 0.078 to 2.643 W,the color of the up-conversion emission can change from red to yellow,and then to green.The flower-shaped nanoparticles have excellent temperature sensing properties,and the maximum absolute sensitivity at 343 K is 0.275 K-1.At the same time,the flower-like nanoparticles NaGd F4:Ce/Tb@NaGd F4:Tb exhibited obvious fluorescence quenching in the presence of dopamine.The detection range of dopamine was 0.05-250?M,and the detection limit is design at 6.8 n M.It provides new ideas and references for the development of a new generation of high-sensitivity temperature probes and molecular detection probes. |
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