皮秒激光透射率法表征高分子薄膜双光子吸收截面

苏少昌; 王希军

Volume 4 Issue 1

Feb. 2011

Turn off MathJax

Article Contents

Chinese Optics > 2011 > 4(1): 82-85.

SU Shao-chang, WANG Xi-jun. Measurement of TPA cross-section of organic material films based on picosecond laser nonlinear transmittance method[J]. Chinese Optics, 2011, 4(1): 82-85.

Citation:

SU Shao-chang, WANG Xi-jun. Measurement of TPA cross-section of organic material films based on picosecond laser nonlinear transmittance method[J]. Chinese Optics, 2011, 4(1): 82-85.

SU Shao-chang, WANG Xi-jun. Measurement of TPA cross-section of organic material films based on picosecond laser nonlinear transmittance method[J]. Chinese Optics, 2011, 4(1): 82-85.

Citation:

SU Shao-chang, WANG Xi-jun. Measurement of TPA cross-section of organic material films based on picosecond laser nonlinear transmittance method[J]. Chinese Optics, 2011, 4(1): 82-85.

PDF( 587 KB)

Measurement of TPA cross-section of organic material films based on picosecond laser nonlinear transmittance method

SU Shao-chang^1,2,
WANG Xi-jun¹

1.
Changchun Institute of Optics,Fine Mechanics and Physics, Chinese Academy of Sciences,Changchun 130033,China;
2.
Graduate University of Chinese Academy of Sciences,Beijing 100049,China

Received Date: 17 Aug 2010
Rev Recd Date: 25 Oct 2010
Publish Date: 25 Feb 2011

Abstract

Abstract

In order to measure the Two Photon Absorption(TPA) cross section of organic material films, a new approach to measure the TPA cross section of a azo dye film based on the nonlinear transmission methods by a low power picosecond Nd∶ YVO4 laser was presented. Firstly, a multi-layered equivalent film sample(5 layers, 20 mm20 mm) with the same thickness for each layer was prepared. The film from an azo dye material was spun and coated on a large PC substrate and then it was cut into 20 mm20 mm clips. Furthermore, a mode-locked Nd∶ YVO4 picosecond laser(1 064 nm, 56.8 MHz, 20 ps) was chosen as the pump source to excite the sample. Finally, the nonlinear transmittance of the five-equivalent layer film was measured and the curve of the experimental data was fitted. Obtained result shows the value of the TPA cross section of this dye molecule is 634.2 GM. Compared with other methods, this experimental scheme is very simple and valid.
- organic material film,
- Two Photon Absorption(TPA) cross-section,
- nonlinear transmittance method,
- picosecond laser

FullText(HTML)

References(1)

References

[1] BIRNBAUM M. Semiconductor surface damage produced by ruby lasers[J]. J. Appl. Phys.,1965,36:3688-3689. [2] van DRIEL H M,SIPE J E,YOUNG J F. Laser-induced periodic surface structure on solids:a universal phenonmenon[J]. Phys. Rev. Lett.,1982,49(26):1955-1958. [3] CRAWFORD T H R,HAUGEN H K. Sub-wavelength surface structures on silicon irradiated by femtosecond laser pulses at 1300 and 2100 nm wavelengths[J]. Appl. Surf. Sci.,2007,253:4970-4977. [4] YOUNG J F,PRESTON J S,van DRIEL H M,et al.. Laser-induced periodic surface structure. II. experiments on Ge, Si, Al, and brass[J]. Phys. Rev. B,1983,27(2):1155-1172. [5] YONG J E,SIPE J E,van DRIEL H M. Laser-induced periodic surface structure. III. Fluence regimes,the role of feedback,and details of the induced topography in germanium[J]. Phys. Rev. B,1984,30(4):2001-2015. [6] 戴玉堂,徐刚,崔健磊, 等 .GaN基半导体材料的157 nm激光微刻蚀[J]. 中国激光 ,2009,36(12):3138-3142. DAI Y T,XU G,CUI J L,et al.. Micro etching of GaN-based semiconductor materials using 157 nm laser[J]. Chinese J. Lasers,2009,36(12):3138-3142.(in Chinese) [7] 石岩,张宏,徐春鹰.铜基粉末冶金摩擦材料激光表面改性处理[J]. 中国激光 ,2009,36(5):1246-1250. SHI Y,ZHANG H,XU CH Y. Laser surface modification of copper-based powder metallurgy friction materials[J]. Chinese J. Lasers,2009,36(5):1246-1250.(in Chinese) [8] 虞钢,王恒海,何秀丽.具有特定光强分布的激光表面硬化技术[J]. 中国激光 ,2009,36(2):480-486. YU G,WANG H H,HE X L. Laser surface hardening using determined intensity distribution[J]. Chinese J. Lasers,2009,36(2):1688-1691.(in Chinese) [9] HER T H,FINLAY R J,WU C,et al.. Microstructuring of silicon with femtosecond laser pulses[J]. Appl. Phys. Lett.,1998,73(12):1673-1675. [10] YOUNKIN R,CAREY J E,MAZUR E,et al.. Infrared absorption by conical silicon microstructures made in a variety of background gases using femtosecond-laser pulses[J]. J. Appl. Phys.,2003,93 (5):2626-2629. [11] 李平,王煜,冯国进, 等 . 超短激光脉冲对硅表面微构造的研究[J]. 中国激光 ,2006,33(12):1688-1691. LI P,WANG Y,FENG G J,et al.. Study of silicon micro-structuring using ultra-short laser pulses[J]. Chinese J. Lasers,2006,33(12):1688-1691.(in Chinese) [12] CROUCH C H,CAREY J E,SHEN M,et al.. Infrared absorption by sulfur-doped silicon formed by femtosecond laser irradiation[J]. Appl. Phys. A,2004,79:1635-1641. [13] KARABUTOV A V,SHAFEEV G A,BADI N,et al.. 3D periodic structures grown on silicon by radiation of a pulsed Nd∶ YAG laser and their field emission properties[J]. Appl. Surf. Sci.,2006,252:4453-4456. [14] CROUCH C H,CAREY J E,WARRENDER J M,et al.. Comparison of structure and properties of femtosecond and nanosecond laser structured silicon[J]. Appl. Phys. Lett.,2004,84(11):1850-1852. [15] JIMNEZ-JARQUN J,HARO-PONIATOWSKI E,FERNNADEZ-GUASTI M,et al.. Laser induced micro-structuring of silicon under different atmospheres[J]. Radiat Eff. Defects Solids,2009,164(7-8):443-451. [16] PEDRAZA A J,FOWLKES J D,LOWNDES D H. Silicon microcolumn arrays grown by nanosecond pulsed-excimer laser irradiation[J]. Appl. Phys. Lett.,1999,74(16):2322-2324. [17] CHUANG T J. Multiple photo excited SF₆ interaction with silicon surfaces[J]. J. Chem. Phys.,1981,74 (2):1453-1460. [18] SAJAD B,PARVIN P,BASSAM M. SF₆ decomposition and layer formation due to excimer laser photoablation of SiO₂ surface at gas-solid system[J]. J. Phys. D:Appl. Phys.,2004,37:3402-3408. [19] LOWNDES D H,FOWLKES J D,PEDRAZA A J. Early stages of pulsed-laser growth of silicon microcolumns and microcones in air and SF₆[J]. Appl. Surf. Sci.,2000,154-155:647-658. [20] DOLGAEV S I,LAVRISHEV S V,LYALIN A A,et al.. Formation of conical microstructures upon laser evaporation of solids[J]. Appl. Phys. A,2001,73:177-181. [21] EMEL'YANOV V I,BABAK D V. Defect capture under rapid solidication of the melt induced by the action of femtosecond laser pulses and formation of periodic surface structures on a semiconductor surface[J]. Appl. Phys. A,2002,74:797-805. [22] BLOEMBERGEN N. Fundaments of laser-solid interactions[J]. Conference on Laser Solid Interactions and Laser Processing. AIP Conf. Proc.,New York,1979,50:1-9. [23] JANNITTI E,MALVEZZI A M,TONODELLO G. Analysis of the radiation backscattered from a laser-produced plasma[J]. J. Appl. Phys.,1975,46 (7):3096-3101.

Relative Articles

Supplements(0)

Cited By

Proportional views