[1] Zhao Y, Zhang Y, Zheng M, Dong X, Duan X, Zhao Z. Three-dimensional luneburg lens at optical frequencies[J]. Laser & Photonics Review,2016, 10(4): 665-672.
[2] Sun Z, Dong X, Chen W, Nakanishi S, Duan X, Kawata S. Multicolor polymer nanocomposites: in situ synthesis and fabrication of 3D microstructures[J]. Advanced Materials,2008, 20(5): 914-919.
[3] Kawata S, Sun H. B, Tanaka T, Takada K. Finer features for functional microdevices[J].Nature,2001, 412: 697-698.
[4] Kumi G, Yanez C, Belfield K, Fourkas J. High-speed multiphoton absorption polymerization: fabrication of microfluidic channels with arbitrary cross-sections and high aspect ratios[J]. Lab on a Chip,2010,10(8): 1057-1060.
[5] Xing J, Chen W, Gu J, Dong X, Takeyasu N, Tanaka T, Duan X, Kawata S. Design of high efficiency for two-photon polymerization initiator: combination of radical stabilization and large two-photon cross-section achieved by N-benzyl 3,6-bis(phenylethynyl)carbazole derivatives[J]. Journal of Materials Chemistry,2007, 17(14): 1433-1438.
[6] Sun H, Matsuo S, Misawa H. Three-dimensional photonic crystal structures achieved with two-photonabsorption photopolymerization of resin[J]. Applied Physics Letters,1999, 74(6): 786-788.
[7] Nguyen L, Straub M, Gu M. Acrylate-based photopolymer for two-photon microfabrication and photonic applications[J]. Advanced Functional Materials,2005, 15(2): 209-216.
[8] Reinhardt B, Brott L, Clarson S, Dillard A, Bhatt J, Kannan R, Yuan L, He G, Prasad P. Highly active two-photon dyes: design, synthesis, and characterization toward application[J]. Chemistry of Materials,1998, 10(7): 1863-1874.
[9] Albota M, Beljonne D, Brédas J, Ehrlich J, Fu J, Heikal A, Hess S, Kogej T, Levin M, Marder S, McCord-Maughon D, Perry J, Röckel H, Rumi M, Subramaniam G, Webb W, Wu X, Xu C. Design of organic molecules with large two-photon absorption cross sections[J]. Science,1998, 281(5383): 1653-1656.
[10] Pond S, Rumi M, Levin M, Parker T, Beljonne D, Day M, Brédas J, Marder S, Perry J. One- and two-photon spectroscopy of donor-acceptor-donor distyrylbenzene derivatives: effect of cyano substitution and distortion from planarity[J]. The Journal of Physical Chemistry A, 2002, 106(47): 11470-11480.
[11] Ahn T, Kim K, Kim D, Noh S, Aratani N, Ikeda C, Osuka A, Kim D. Relationship between two-photon absorption and the π-conjugation pathway in porphyrin arrays through dihedral angel control[J]. Journal of the American Chemical Society,2006, 128(5): 1700-1704.
[12] Mongin O, Porres L, Charlot M, Katan C, Blanchard-Desce M. Synthesis, fluorescence, and two-photon absorption of a series of elongated rodlike and banana-shaped quadrupolar fluorophores: a comprehensive study of structure-property relationships[J]. Chemistry-A European Journal, 2007, 13(5): 1481-1498.
[13] Ventelon L, Charier S, Moreaux L, Mertz J, Blanchard-Desce M. Nanoscale push-push dihydrophenanthrene derivatives as novel fluorophores for two-photon-excited fluorescence[J]. Angewandte Chemie International Edition, 2001, 40(11): 2098-2101.
[14] Senge M, Fazekas M, Notaras E, Blau W, Zawadzka M, Locos O, Mhuircheartaigh E. Nonlinear optical properties of porphyrins[J]. Advanced Materials, 2007, 19(19): 2737-2774.
[15] Williams-Harry M, Bhaskar A, Ramakrishna G, Goodson T, Imamura M, Mawatari A, Nakao K, Enozawa H, Nishinaga T, Iyoda M. Giant thienylene-ethylene macrocycles with large two-photon absorption cross section and semishape-persistence[J]. Journal of the American Chemical Society, 2008, 130(11): 3252-3253.
[16] Rumi M, Ehrlich J, Heikal A, Perry J, Barlow S, Hu Z, Mccord-Maughon D, Parker T, Röckel H, Thayumanavan S, Marder S, Beljoinne D, Bredas J. Structure-property relationships for two-photon absorbing chromophores: bis-donor diphenylpolyene and bis(styryl)benzene derivatives[J].Journal of the American Chemical Society, 2000, 122(39): 9500-9510.
[17] Li Z, Pucher N, Cicha K, Torgersen J, Ligon S, Ajami A, Husinsky W, Rosspeintner A, Vauthey E, Naumov S, Scherzer T, Stampfl J, Liska R. A straightforward synthesis and structure-activity relationship of highly efficient initiators for two-photon polymerization[J]. Macromolecules, 2013, 46(2): 352-361.
[18] Zhang X, Yu X, Sun Y. Synthesis and nonlinear optical properties of two new two-photon initiators: triphenylamine derivatives[J]. Optical Materials, 2006, 28(12): 1366-1371.
[19] Yan Y, Tao X, Sun Y, Xu G, Wang C, Yang J, Zhao X, Wu Y, Ren Y, Jiang M. Two new asymmetrical two-photon photopolymerization initiators: synthesis, characterization and nonlinear optical properties[J]. Optical Materials, 2005, 27(12): 1787-1792.
[20] Yan Y, Tao X, Sun Y, Yu W, Wang C, Xu G, Yang J, Zhao X, Jiang M. Synthesis, structure and nonlinear optical properties of a two-photon photopolymerization initiator[J].Journal of Materials Science,2005, 40(3): 597-600.
[21] 田凯军,李秀平,胡 睿,王双青,李沙瑜,杨国强. 新型双光子吸收化合物的合成、光物理及其在固态分散体系中的性质[J]. 中国科学:化学,2011,41(8): 1372-1378. Tian K J, Li X P, Hu R, Wang S Q, Li S Y,Yang G Q.Synthesis and photophysical properties of novel two-photon absorption chromophores and research on its solid-state device[J]. Science China:Chemistry, 2011,41(8): 1372-1378.
[22] Wu J, Shi M,Zhao Y, Wu F. Two-photon absorption property and photopolymerization sensitizing efficiency of asymmetrical benzylidene cyclopentanone dyes[J]. Dyes and Pigments, 2008, 76(3): 690-695.
[23] Zheng M, Fujita K, Chen W, Smith N, Duan X, Kawata S. Comparison of staining selectivity of subcellular structures by carbazole-based cyanine probes for nonlinear optical microscopy[J]. ChemBioChem, 2011, 12(1): 52-55.
[24] Zheng Y, Zheng M, Chen S, Zhao Z, Duan X.Biscarbazolylmethane-based cyanine: a two-photon excited fluorescent probe for DNA and selective cell imaging[J]. Journal of Materials Chemistry B,2014, 2(16): 2301-2310.
[25] Kang R, Zheng M, Chen W, Zhao Z, Duan X. Bright fluorescent hollow structural nanoparticles prepared from amphiphilic molecules with C2v symmetry[J]. RSC Advances, 2012, 2(28): 10478-10480.
[26] Zheng Y, Zheng M, Li K, Chen S, Zhao Z, Wang X, Duan X. Novel carbazole-based two-photon photosensitizer for efficient DNA photocleavage in anaerobic condition using near-infrared light[J]. RSC Advances, 2015, 5(1): 770-774.
[27] Chen S, Zheng Y, Zheng M, Dong X, Jin F, Zhao Z, Duan X. Nondegenerate two-photon absorption properties of a newly synthesized carbazole derivative[J]. Journal of Materials Chemistry C, 2017, 5(2): 470-475.
[28] Gu J, Wang Y, Chen W, Dong X, Duan X, Kawata S. Carbazole-based 1D and 2D hemicyanines: synthesis, two-photon absorption properties and application for two-photon photopolymerization 3D lithography[J]. New Journal of Chemistry,2007, 31(1): 63-68.
[29] Xing J, Dong X, Chen W, Duan X, Takeyasu N, Tanaka T, Kawata S. Improving spatial resolution of two-photon microfabrication by using photoinitiator with high initiating efficiency[J]. Applied Physics Letters,2007, 90(13): 131106.
[30] Xing J, Zheng M, Chen W, Dong X, Takeyasu N, Tanaka T, Zhao Z, Duan X, Kawata S. C2v Symmetrical two-photon polymerization initiators with anthracene core: synthesis, optical and initiating properties[J]. Physical Chemistry Chemical Physics, 2012, 14(45): 15785-15792.
[31] Xing J, Liu J, Zhang T, Zhang L, Zheng M, Duan X. A water soluble initiator prepared through host-guest chemical interaction for microfabrication of 3d hydrogels via two-photon polymerization[J]. Journal of Materials Chemistry B, 2014, 2(27): 4318-4323.
[32] Xing J, Liu L, Song X, Zhao Y, Zhang L, Dong X, Jin F, Zheng M, Duan X. 3D hydrogels with high resolution fabricated by two-photon polymerization with sensitive water soluble initiator[J]. Journal of Materials Chemistry B, 2015, 3(43): 8486-8491.
[33] Gou X, Zheng M, Zhao Y, Dong X, Jin F, Xing J, Duan X. Mechanical property of PEG hydrogel and the 3D red blood cell microstructures fabricated by two-photon polymerization[J]. Applied Surface Science, 2017, 416(1): 273-280.
[34] Zhao Y, Li X, Wu F, Fang X. Novel multi-branched two-photo polymerization initiators of ketocoumarin derivatives[J]. Journal of Photochemistry and Photobiology A: Chemistry,2006, 177(1): 12-16.
[35] Wu J, Zhao Y, Li X, Shi M, Wu F, Fang X. Multibranched benzylidene cyclopentanone dyes with large two-photon absorption cross-sections[J]. New Journal of Chemistry, 2006, 30(7): 1098-1103.
[36] Wang X, Jin F, Chen Z, Liu S, Tao X, Duan X, Jiang M. A new family of dendrimers with naphthaline core and triphenylamine branching as a two-photon polymerization initiator[J]. The Journal of Physical Chemistry C, 2011, 115(3): 776-784.
[37] Wang X, Jin F, Zhang W, Tao X, Duan X. Novel D-π3-(A)1-3 multibranched chromophores as an efficient two-photon-induced polymerization initiator[J]. Dyes and Pigments, 2011, 88(1): 57-64.
[38] Dong X, Zhao Z, Duan X. Improving spatial resolution and reducing aspect ratio in multiphoton polymerization nanofabrication[J]. Applied Physics Letters, 2008, 92(9): 091113.
[39] Li L, Gattass R, Gershgoren E, Hwang H, Fourkas J. Achieving 20 resolution by one-color initiation and deactivation of polymerization[J]. Science,2009, 324(5929): 910-913.
[40] Takada K, Wu D, Chen Q, Shoji S, Xia H, Kawata S, Sun H. Size-dependent behaviors of femtosecond laser-prototyped polymer micronanowires[J]. Optics Letters, 2009, 34(5): 566.
[41] Tan D, Li Y, Qi F, Yang H, Gong Q, Duan X. Reduction in feature-size of two-photon polymerization using SCR500[J]. Applied Physics Letters, 2007, 90(7): 071106.
[42] Gan Z, Cao Y, Evans R, Gu M, Three-dimensional deep sub-diffraction optical beam lithography with 9 nm feature size[J]. Nature Communications, 2013, 4: 2061.
[43] Coenjarts C, Ober C. Two-photon three-dimensional microfabrication of poly(dimethylsiloxane) elastomers[J]. Chemistry of Materials, 2004, 16(26): 5556-5558.
[44] Cumpston B, Ananthavel S, Barlow S, Dyer D, Ehrlich J, Erskine L, Heikal A, Kuebler S, Lee I, McCord-Maughon D, Qin J, Röckel H, Rumi M, Wu X, Marder S, Perry J. Two-photon polymerization for three-dimensional optical data storage and microfabrication[J]. Nature, 1999, 398: 51-54.
[45] Lee J, George M, Moore J, Braun P. Multiphoton writing of three-dimensional fluidic channels within a porous matrix[J]. Journal of the American Chemical Society, 2009, 131(32): 11294-11295.
[46] Cao H, Zheng M, Dong X, Jin F, Zhao Z, Duan X. Two-photon nanolithography of positive photoresist thin film with ultrafast laser direct writing[J]. Applied Physics Letters, 2013, 102(20): 201108, 1-4.
[47] Zhao Y, Zhang Y, Zheng M, Dong X, Duan X, Zhao Z. Anisotropic and omnidirectional focusing in luneburg lens structure with gradient photonic crystals[J]. Journal of Optics, 2016, 19(2017): 015605.
[48] 赵圆圆,郑美玲,段宣明. 飞秒激光微纳3D打印新进展——首次实现微尺度光波段3D Luneburg透镜[J]. 物理, 2016, 45(11): 729-731. Zhao Y Y, Zheng M L, Duan X M. New progress of micro 3D printing by femtosecond laser—first realization of 3D Luneburg lens at optical frequencies in microscale[J]. Physics, 2016, 45(11): 729-731.
[49] 贾雁鹏,郑美玲,董贤子,赵震声,段宣明. 双光子微纳加工技术结合化学镀工艺制备三维金属微弹簧结构[J]. 影像科学与光化学,2014, 32(6): 542-549. Jia Y P, Zheng M L, Dong X Z, Zhao Z S, Duan X M. 3D metallic micro-spring fabrication based on two-photon micro/nano fabrication method and electroless plating technique[J]. Imaging Science and Photochemistry, 2014, 32(6): 542-549.
[50] Wang W, Sun Z, Zheng M, Dong X, Zhao Z, Duan X. Magnetic nickel phosphorus/polymer composite and remotely driven three-dimensional micromachine fabricated by nanoplating and two-photon polymerization[J]. The Journal of Physical Chemistry C, 2011, 115(22): 11275-11281.
[51] Gansel J, Thiel M, Rill M, Decker M, Bade K, Saile V, Freymann G, Linden S, Wegener M. Gold helix photonic metamaterial as broadband circular polarizer[J]. Science, 2009, 325(5947): 1513-1515.
[52] Xing J, Zheng M, Duan X. Two-photon polymerization microfabrication of hydrogels: an advanced 3D printing technology for tissue engineering and drug delivery[J]. Chemical Society Reviews,2015,44(15): 5031-5039.
[53] Xiong Z, Zheng M, Dong X, Chen W, Jin F, Zhao Z, Duan X. Asymmetric microstructure of hydrogel: two-photon microfabrication and stimuli-responsive behavior[J]. Soft Matter, 2011, 7(21): 10353-10359.
[54] Klein F, Striebel T, Fischer J, Jiang Z, Franz C, Freymann G, Wegener M, Bastmeyer M. Elastic fully three-dimensional microstructure scaffolds for cell force measurements[J].Advanced Materials,2010, 22(8): 868-871.
[55] Klein F, Richter B, Striebel T, Franz C, Freymann G, Wegener M, Bastmeyer M. Two-component polymer scaffolds for controlled three-dimensional cell culture[J]. Advanced Materials, 2011, 23(11): 1341-1345. |