Published December 17, 2016
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TYPE 1 & TYPE 2 OPTICAL LIMITING STUDIES IN DISPERSE ORANGE-25 DYE-DOPED PMMA-MA POLYMER FILMS USING CW LASER
- 1. Research Scholar, Department of Chemistry, Rayalaseema University, Kurnool, Andhra Pradesh
- 2. Srinivas Institute of Management Studies, Pandeshwar, Mangalore, Karnataka
- 3. Department of Chemistry, Srinivas Institute of Technology, Valachil, Mangalore, Karnataka
Description
Materials with exceptional third order nonlinear optical properties are critical to the continuing development of photonics and electro-optical devices such as those used in optical communications, networking, optical computation for signal processing, and data storage devices. The nonlinear optical material research is generally focussed on improving the efficiency of optical wavelength conversion, optical amplification, nonlinear absorption, refractive index changes etc. which are input light intensity dependent. During last few years, the organic dye-doped polymer films are getting more attention due to their advantages in fabricatingoptimum photonics devices. In this paper, we have studied the nonlinear optical properties like nonlinear absorption and nonlinear refraction of an azo dye Disperse Orange-25 (DO-25) doped in Polymethyl methacrylate-methacrylic acid (PMMA-MA) polymer matrix using open aperture and closed aperture Z-scan experimental methods for continuous wave (CW) laser input. The optical limiting properties of these films are also studied using Type 1 and Type 2 configurations at different input power using continuous wave (CW) laser beams of 532 nm wavelength.The nonlinear absorption coefficient, nonlinear refractive index, and saturated output power for type 1 and type 2 optical limiting are determined.
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References
- 1. Nalwa, H. S., & Miyata, S. (1996). Nonlinear optics of organic molecules and polymers.CRC press. 2. Bhawalkar, J. D., He, G. S., & Prasad, P. N. (1996). Nonlinear multiphoton processes in organic and polymeric materials. Reports on Progress in Physics, 59(9), 1041. 3. Almosawe, A. J., & Saadon, H. L. (2013). Nonlinear optical and optical limiting properties of new structures of organic nonlinear optical materials for photonic applications. Chinese Optics Letters, 11(4), 041902. 4. Perry, J.W., Mansour, K., Mander, S.R., Perry, K. J., Alverez, D. & Choong, I. (1994). Enhanced reverse saturable absorption and optical limiting in heavy-atom-substituted phthalocyanines, Opt. Lett., 19, 625-627. 5. Shirk, J. S., Pong, R. G., Flom, S. R., Heckmann, H., & Hanack, M. (2000). Effect of axial substitution on the optical limiting properties of indium phthalocyanines. The Journal of Physical Chemistry A, 104(7), 1438-1449. 6. Blau, W., Byrne, H., Dennis, W. M. and Kelly, J. M. (1985). Reverse Saturable absorption in tetraphenylporphyrines, Opt. Commun., 56, 25-29, 1985. 7. Sevian, A., Ravikanth, M. and Kumar, G.R. (1996). Optical limiting in short chain basket handleporphyrins, Chem. Phys. Lett., 263, 241-246, 1996. 8. Sharma, S., Mohan, D., & Ghoshal, S. K. (2008). Measurement of nonlinear properties and optical limiting ability of Rhodamine 6G doped silica and polymeric samples. Optics Communications, 281(10), 2923-2929. 9. Castillo, J., Kozich, V.P. and Marcano, A.O. (1994). Thermal lensing resulting from one and two-photon absorption studied with a two color time-resolved Z-scan. Opt. Lett., 19, 171-173. 10. Krishnamurthy, R. R., & Alkondan, R. (2010). Nonlinear characterization of Mercurochrome dye for potential application in optical limiting. Opt. Appl. XL, 187-196. 11. Rekha, R. K., & Ramalingam, A. (2009). Nonlinear characteristic and optical limiting effect of oil red O azo dye in liquid and solid media. Journal of Modern Optics, 56(9), 1096-1102. 12. Muto, S., Kubo, T., Kurokawa, Y. and Suzuki, K. (1998). Third-order nonlinear optical properties of Disperse Red 1 and Au nanometer-size particle-doped alumina films prepared by sol-gel method.Thin Solid Film, 322, 233-237. 13. Zidan, M. D., &Ajji, Z. (2011). Optical limiting behavior of disperse red 1 dye doped polymer. Optics & Laser Technology, 43(5), 934-937. 14. Brzozowski, L. & Sargent, E. H. (2001). Azobenzenes for photonic network applications: Third–order nonlinear optical properties. J. Material Science: Materials in Electronics, 12, 483-489. 15. Naseema, K., Manjunatha, K. B., Sujith, K. V., Umesh, G., Kalluraya, B., &Rao, V. (2012). Third order optical nonlinearity and optical limiting studies of propane hydrazides. Optical Materials, 34(11), 1751-1757. 16. Venugopal Rao, S., Naga Srinivas, N.K.M. and Narayana Rao, D. (2002). Nonlinear absorption and excited state dynamics in Rhodamine B studied using Z-scan and degenerate four wave mixing techniques, Chem. Phys. Lett., 361, 439-445. 17. Umakanta Tripathy, R., Justin Rajesh, R., Prem, B.B. & Subrahamanyam, (2002).Optical nonlinearity of organic dyes as studied by Z-scan and transient grating techniques.Procs. Indian Acad. Sci. (Chem. Sci.), 114(6), 557-564. 18. Sukumaran, V. S., & Ramalingam, A. (2011). Third order optical nonlinearities and spectral characteristics of methylene blue. Journal of Quantum Information Science, 1(02), 69. 19. Chen, Q., Kuang, L., Sargent, E.H. and Wang, Z.Y. (2003). Ultrafast nonresonant third-order optical nonlinearity of fullerene-containing polyurethane films at telecommunication wavelengths, Appl. Phys. Lett., 83, 2115-2117. 20. Zidan, M. D., Ajji, Z., Allaf, A. W., &Allahham, A. (2011). Investigation of the optical limiting properties of acid blue 29 in various solvents. Optics & Laser Technology, 43(7), 1347-1350. 21. Dharmadhikari, A.K., Roy, B., Roy, S., Dharmadhikari, J.A., Mishra, A. and Kumar, R.G. (2004). Higher-order optical nonlinearities in 4-dimethylamino-N-methyl-4-stilbazolium tosylate. Opt. Commun., 235, 195-200. 22. Ganeev, R.A., Baba, M., Morita, M., Ryasnyansky, A.I., Suzuki, M., Turu, M. and Kuroda, H. (2004). Fifth-order optical nonlinearity of pseudoisocyanine solution at 529 nm, J. Opt. A: Pure Appl. Opt., 6, 282-287. 23. Del Nero, J., de Araujo, R.E., Gomes, A.S.L. and de Melo, C.P. (2005).Theoretical and experimental investigation of the second hyperpolarizabilities of methyl orange, J. Chem. Phys., 122(104506), 1-6. 24. Hassan, Q. M. A., (2015). Optical limiting properties of sudan red B in solution and solid film Optical and Quantum Electronics, 47(2), 297-311. 25. Aithal, P. S., Singh, R. P. &Rao, D. N. (2003). Optical limiting due to frequency up-converted fluorescence in DASPB dye doped polymer matrix. Proceedings of SPIE, 4797, 229-239. 26. Singh, R. P., Aithal, P. S. &Rao, D. N. (2003). Optical limiting studies of Disperse Orange and Disperse Yellow in PMMA-MA matrix.Proc. of SPIE, 4797, 52-58. 27. Jamshidi-Ghaleh, K., Salmani, S., &Ara, M. H. M. (2007). Nonlinear responses and optical limiting behavior of fast green FCF dye under a low power CW He–Ne laser irradiation. Optics Communications, 271(2), 551-554. 28. Shubhrajyotsna Aithal, Aithal, P. S. & Bhat, G. K. (2013).Study of Optical Limiting and Optical Phase Conjugation in DASPB dye-doped polymer films, GSTF Journal of Physics and Applications (JPA), 1(1), 15-24.DOI: 10.5176/2335-6901.1.1.3. 29. Shubhrajyotsna Aithal, Aithal, P. S. & Bhat, G. K. (2012).Study of Degenerate Four-Wave Mixing in Disperse Orange Dye-doped Polymer Film, Advanced Materials Research Journal, 584, 526-530. doi:10.4028/www.scientific.net/AMR.584.526. 30. Shubhrajyotsna Aithal, Aithal, P. S. & Bhat, G. K.(2015),Comparative Study on Azo dye-doped Polymer Films for Optical Phase Conjugation.International Journal of Science and Research (IJSR), 4(4), 436-441. DOI: 10.5281/zenodo.61724. 31. Shubrajyotsna Aithal, Aithal, P. S. & Bhat, G. K. (2013). Degenerate four-wave mixing in DASPB dye-doped polymer film,published in Part IV Quantum Optics, Chapter 12, Advances in Laser Physics and Technology, Edited by Man Mohan, Anil Kumar Maini, Aranya A. Bhattacherjee and Anil K. Razdan under the imprint of Foundation Books, Cambridge University Press India Pvt Ltd., pp. 179 - 195, ISBN: 978-93-844634-1-0.,DOI : 10.5281/zenodo.62048. 32. Shubrajyotsna Aithal, Aithal, P. S. & Bhat, G. K. (2012). Phase Conjugation in Two Photon Absorbing Dye films by Degenerate Four-wave Mixing, 3rd International Conference on Photonics 2012, 1-3 October 2012, Penang, Malaysia. Published in IEEE Xplore ISBN: 978-1-4673-1463-3, pp.235-239. 33. Shubrajyotsna Aithal, Aithal, P. S. & Bhat, G. K. (2012). Study of Degenerate Four-Wave Mixing in Disperse Orange Dye-doped Polymer Film, Advanced Materials Research Journal, 584, 526-530. 34. Shubrajyotsna Aithal, Aithal, P. S. (2012). Study of Phase Conjugated wave in DASPB dye-doped polymer films, Photonics Global Conference 2012, 13-16, December 2012, Nanyang Technical University, Singapore.In Photonics Global Conference (PGC), Singapore, pp.1-5.IEEE.ISBN : 978-1-4673-2513-4, DOI:10.1109/PGC.2012.6458057. 35. Shubrajyotsna Aithal, Aithal, P. S. & Bhat, G. K. (2016). Study of Low Power Degenerate Four-Wave Mixing in Disperse Yellow Dye-doped Polymer Film.International Journal of Engineering Research and Modern Education (IJERME), 1(2), 200-209. DOI: http://dx.doi.org/10.5281/ZENODO.198716. 36. Aithal, P. S. (2016). Review on Various Ideal System Models Used to Improve the Characteristics of Practical Systems. International Journal of Applied and Advanced Scientific Research, 1(1), 47-56. DOI : http://doi.org/10.5281/zenodo.159749 37. Van Stryland, E. W., Wu, Y. Y., Hagan, D. J., Soileau, M.J. &Kamjou Mansour (1988). Optical Limiting with Semiconductors.JOSA B5, 1980-1989. 38. Yee, K. C. Tou, T.Y. & Ng, S. W. (1998). Hot-press molded PMMA matrix for solid-state dye lasers. Applied Optics, 37, 6381-6385. 39. Shubhrajyotsna Aithal, Aithal, P. S. & Bhat, G. K. (2011). Nonlinear Absorption Studies of Disperse Orange Doped Polymer Film, Trends in Optics and Photonics II, Proceedings of International Conference on Trends in Optics and Photonics, December 7-9, 2011, Kolkata, India. Editors: Ajay Ghosh and Debesh Choudhury, ISBN 978-81-908188-1-0, P. 132-137, (2011), DOI : 10.5281/zenodo.62034. 40. Shubrajyotsna Aithal, Aithal, P. S. & Bhat, G. K. (2015). A Review on Sustainable Organic Materials for Optical Limiting Technology.International Journal of Management, IT and Engineering (IJMIE), 5(7), 527-544, DOI: 10.5281/zenodo.62032. 41. Sheik-Bahae, M., Said, A. A. & Van Strayland, E. W. (1989). High Sensitivity Single beam n2 Measurement. Opt. Lett., 14, 955-957. 42. Sheik-Bahae, M., Said, A. A., Wei, T., Hagan, D. J. and Van Strayland, E.W. (1990). Sensitivitive measurement of optical nonlinearities using a single beam. IEEE J. Quantum Electron. 26, 760-769. 43. Rekha, R. K. & Ramalingam, A. (2009). Non-linear characterization and optical limiting effect of carmine dye. Indian Journal of Science and Technology, 2(8), 27-31. 44. Cassano T, Tommasi R, Ferrara M, Babudri F, Farinola GM and Naso F (2001). Substituent dependence of the optical nonlinearities in poly (2, 5-dialkoxy-pphenylenevinylene) polymers investigated by the Z-scan technique. Chem. Phys. 272,111-118. DOI: 10.1016/S0301-0104(01)00453. 45. Rajashekar, B. Sagar Limbu, Kamarusu Aditya, Nageswara Rao, G. & Siva Sankara Sai, S. (2013). Azo doped polymer thin films for active and passive optical power limiting applications. Photochem. Photobiol. Sci., 12(10), 1780-1786. 46. Nagaraja, K. K., Pramodini, S., Santhosh Kumar, A. Nagaraja, H. S., Poornesh, P. & Dhananjaya Kekuda. (2013). Third-order nonlinear optical properties of Mn doped ZnO thin films under cw laser illumination. Optical Materials. 35 (3), 431–439. 47. Pradeep, C., Mathew, S., Nithyaja, B., Radhakrishnan, P. and Nampoori, V.P.N., (2014). Studies of nonlinear optical properties of PicoGreen dye using Z-scan technique, Applied Physics A, 115, 291-295. 48. Shubrajyotsna Aithal, Aithal, P. S. & Bhat, G. K. (2011). Optical Nonlinearity of Dye-doped Polymer Film using Z-scan Technique. Proceedings of Second International Conference on Photonics 2011, Kota Kinabalu, Malaysia, IEEE Xplore, ISBN 978-1-61284-265-3, pp 62-66. DOI: 10.1109/ICP. 2011.6106884. 49. Shubrajyotsna Aithal, Aithal, P. S. & Bhat, G. K. (2011). Study of nonlinear absorption in a dye doped polymer film due to frequency up-converted fluorescence. Proceedings of the International Conference on Laser, Material Science and Communication, Ed. Chatterjee, U. & Chakrabarti, P. K. ISBN : 978-93-80813-14-1, pp. 107-109, (2011), DOI : 10.5281/zenodo.62033. 50. Shubrajyotsna Aithal, Aithal, P. S. & Bhat, G. K. (2012). Phase Conjugation in Two Photon Absorbing Dye films by Degenerate Four-wave Mixing, 3rd International Conference on Photonics 2012, Malaysia. IEEE Xplore ISBN: 978-1-4673-1463-3, pp - 235-239. DOI: 10.1109/ICP.2012.6379868. 51. Shubrajyotsna Aithal, Aithal, P. S. & Bhat, G. K. (2015). A Review on Sustainable Organic Materials for Optical Limiting Technology. International Journal of Management, IT and Engineering (IJMIE), 5(7), 527-544. DOI: 10.5281/zenodo.62032. 52. Shubhrajyotsna Aithal, & Aithal P. S., (2016). ABCD analysis of Dye doped Polymers for Photonic Applications, IRA-International Journal of Applied Sciences, 4(3), 358-378. DOI: http://dx.doi.org/ 10.21013/jas.v4.n3.p1. 53. Kaladevi, S. Vijayan, C. Kothiyal, M.P. (2004). Opt. Mater. 27, 1606. 54. Balaji, G. Rekha R. K. & Ramalingam, A. (2011). Nonlinear Characterization of Safranin O Dye for Application in Optical Limiting.ACTA PHYSICA POLONICA A, 119(3), 359-363.