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应用溶胶-凝胶技术, 成功地把5,10,15,20-四(4-磺酸苯基)卟啉铜掺杂到SiO2/TiO2无机凝胶中, 制备成有机-无机复合材料. 采用开孔Z-扫描技术, 使用波长532 nm、脉宽7ns的YAG脉冲激光为光源, 测定了不同浓度卟啉铜掺杂的SiO2/TiO2凝胶Z-扫描曲线. 应用Z扫描理论对获得的曲线进行分析与理论拟合, 得到复合材料的非线性吸收系数. 这些非线性吸收是由材料中卟啉铜的单聚体与二聚体的反饱和吸收所引起. 研究表明, 随着掺杂浓度的增大, 复合材料的非线性吸收明显增强. 掺杂浓度为1.11×10-4 (A2), 1.48×10-4 (A3)与3.01×10-4 mol/L (A4)凝胶的非线性吸收系数分别为1.705×10-11, 1.892×10-11和4.854×10-11 m/W. 讨论了单聚体与二聚体的浓度变化对非线性吸收的影响. 随着掺杂浓度的增加, 凝胶中二聚体与多聚体含量的增加, 导致非线性吸收系数的增大. 同时测定了无机材料对该光源的抗激光损伤阈值为~5 J/cm2.The Cu(II)meso-tetra(4-sulfonatopheny1) porphines (Cu(II)-TPPS) with various concentrations are incorporated into TiO2/SiO2 to form organic and inorganic composite gels via sol-gel process. With a Nd:YAG laser of 532 nm wavelength and 7 ns pulse width, the curves of Z-scan are measured under the condition of open aperture. Nonlinear absorption parameters of these materials, which are attributed to the reverse saturation absorptions of monomer and dimer of Cu(II)-TPPS, are obtained by fitting the above curves with Z-scan theroy. The result indicates that the nonlinear parameter of gel increases with doping concentration increasing. The nonlinear absorption coefficients of gels in 1.11×10-4 mol/L A2, 1.48×10-4 mol/L A3 and 3.01×10-4 mol/L A4 doping concentration are 1.705×10-11, 1.892×10-11, and 4.854×10-11 m/W, respectively. The effects of monomer and dimer on the nonlinear parameter are discussed. The reduction of the nonlinear parameter results from the increases of dimer and multimer as the doping concentration increases. The damage threshold of the gel is also measured and can reach up to ~5 J/cm2.
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Keywords:
- sol-gel /
- porphine /
- Z-scan /
- optical limiting
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[1] Shekhar G, Keith K, Pamela P 1992 Opt. Lett. 17 264
[2] Cai X W, Liu C Y, Ding X M, Gu Y, Liu F G 2005 J. Opt. Laser 3 376 (in Chinese) [蔡雄伟, 刘承宜, 丁新民, 顾瑛, 刘凡光 2005 光电子· 激光 3 376]
[3] Bezerra A G, Borissevitch I E, Gomes A S L 2000 Opt. Lett. 25 323
[4] Chen H X, Yan M, Song W B 2002 New Chemical Materials 30 35 (in Chinese) [陈红祥, 严煤, 孙文博 2002 化工新型材料 30 35]
[5] Dou K, Sun X D, Wang X J, Parkhill R, Guo Y, Knobbe E T 1999 IEEE J. Quantum Electron. 35 1004
[6] Arun K S, Bipin B, Braja K M, Chen L 1995 Macromolecules 28 5681
[7] Sheik B M, Said A A, Wei T W 1990 IEEE J. Quantum Electron. 26 760
[8] Zhang X H, Wang D J, Xia H P 2011 Acta Phys. Sin. 60 024210 (in Chinese) [张晓荷, 王冬杰, 夏海平 2011 60 024210]
[9] Wan Q, Wang T H, Lin C L 2003 Nanotechnology 14 L15
[10] Hyun S C, Hanju R, Jae K S 2003 J. Am. Chem. Soc. 125 5850
[11] Zhang X H, Xia H P, Wang D J 2011 J. Chin Ceram Soc. 39 125 (in Chinese) [张晓荷, 夏海平, 王冬杰 2011 硅酸盐学报 39 125]
[12] He Y H, Hui R J, Yi Y P, Shuai Z G 2008 Acta Phys. Chim. Sin. 24 565 (in Chinese) [何远航, 惠仁杰, 易院平, 帅志刚 2008 物理化学学报 24 565]
[13] Zhang B, Liu Z B, Chen S Q, Zhou W Y, Zang W P, Tian J G, Luo D B, Zhu Z A 2007 Acta Phys. Sin. 56 5252 (in Chinese) [张冰, 刘智波, 陈树琪, 周文远, 臧维平, 田建国, 罗代兵, 朱志昂 2007 56 5252]
[14] Sun J, Fan H L, Wang X Q 2009 Chin. Opt. Lett. 9 2417 (in Chinese) [孙晶, 范贺良, 王新强 2009 中国激光 9 2417]
[15] Zhang K, Wang F F, Zhu B H, Gu Y Z, Guo L J 2010 Acta Photon. Sin. 39 11 (in Chinese) [张琨, 王芳芳, 朱宝华, 顾玉宗, 郭立俊 2010 光子学报 31 11]
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