Laser & Optoelectronics Progress, Volume. 60, Issue 21, 2116004(2023)
Application of NaYbF4∶Tm3+ Upconversion Microcrystals in Near-Infrared-Induced Photopolymerization
[1] Yagci Y, Jockusch S, Turro N J. Photoinitiated polymerization: advances, challenges, and opportunities[J]. Macromolecules, 43, 6245-6260(2010).
[2] Zhu J Z, Zhang Q, Yang T Q et al. 3D printing of multi-scalable structures via high penetration near-infrared photopolymerization[J]. Nature Communications, 11, 3462(2020).
[3] Zhang X M, Xue P, Yang X et al. Near-infrared light-driven shape-programmable hydrogel actuators loaded with metal-organic frameworks[J]. ACS Applied Materials & Interfaces, 14, 11834-11841(2022).
[4] Mariani A, Bidali S, Fiori S et al. UV-ignited frontal polymerization of an epoxy resin[J]. Journal of Polymer Science Part A: Polymer Chemistry, 42, 2066-2072(2004).
[5] Zou X C, Zhao Y Q, Zhu Y et al. Filling aggregation-induced extinction mechanism in near-infrared photopolymerization for gradient and highly filled bulk materials[J]. Macromolecules, 55, 2075-2084(2022).
[6] Xiao Q B, Ji Y T, Xiao Z H et al. Novel multifunctional NaYF4: Er3+, Yb3+/PEGDA hybrid microspheres: NIR-light-activated photopolymerization and drug delivery[J]. Chemical Communications, 49, 1527-1529(2013).
[7] Liu R, Chen H, Li Z Q et al. Extremely deep photopolymerization using upconversion particles as internal lamps[J]. Polymer Chemistry, 7, 2457-2463(2016).
[8] Zou X C, Zhu J Z, Zhu Y et al. Photopolymerization of macroscale black 3D objects using near-infrared photochemistry[J]. ACS Applied Materials & Interfaces, 12, 58287-58294(2020).
[9] Li Z Q, Zou X C, Shi F et al. Highly efficient dandelion-like near-infrared light photoinitiator for free radical and thiol-ene photopolymerizations[J]. Nature Communications, 10, 3560(2019).
[10] Zhang F, Li J, Shan J et al. Shape, size, and phase-controlled rare-Earth fluoride nanocrystals with optical up-conversion properties[J]. Chemistry, 15, 11010-11019(2009).
[11] Liu B L, Wang H Y, Sun X L et al. Self-assemble micron NaYbF4: Er via controllable synthesis[J]. Journal of Changchun University of Science and Technology (Natural Science Edition), 38(2015).
[12] Würth C, Fischer S, Grauel B et al. Quantum yields, surface quenching, and passivation efficiency for ultrasmall core/shell upconverting nanoparticles[J]. Journal of the American Chemical Society, 140, 4922-4928(2018).
[13] Hu P, Xu H, Pan Y et al. Laser induced thermal effect on the polymerization behavior in upconversion particle assisted near-infrared photopolymerization[J]. Chemphyschem, 23, 202100670(2022).
[14] Wei Y, Lu F Q, Zhang X R et al. Synthesis of oil-dispersible hexagonal-phase and hexagonal-shaped NaYF4: Yb, Er nanoplates[J]. Chemistry of Materials, 18, 5733-5737(2006).
[15] Zhuang J L, Liang L F, Sung H H Y et al. Controlled hydrothermal growth and up-conversion emission of NaLnF4 (Ln=Y, Dy-Yb)[J]. Inorganic Chemistry, 46, 5404-5410(2007).
[16] Chen B, Kong W, Wang N et al. Oleylamine-mediated synthesis of small NaYbF4 nanoparticles with tunable size[J]. Chemistry of Materials, 31, 4779-4786(2019).
Get Citation
Copy Citation Text
Hang Xu, Peng Hu, Xinxin Sang, Feng Shi, Ren Liu. Application of NaYbF4∶Tm3+ Upconversion Microcrystals in Near-Infrared-Induced Photopolymerization[J]. Laser & Optoelectronics Progress, 2023, 60(21): 2116004
Category: Materials
Received: Oct. 17, 2022
Accepted: Nov. 30, 2022
Published Online: Oct. 26, 2023
The Author Email: Liu Ren (liuren@jiangnan.edu.cn)