Modeling of Doped ZnO Waveguides for Nonlinear Applications

Rosmin Elsa Mohan; K.S. Sreelatha; M. Sivakumar; A. Krishnashree

doi:10.4028/www.scientific.net/AMR.403-408.3753

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HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 403-408Modeling of Doped ZnO Waveguides for Nonlinear...

Modeling of Doped ZnO Waveguides for Nonlinear Applications

Abstract:

In this paper, the modeling investigations of ZnO planar waveguides with varying refractive indices are quoted. The nature of field mode propagations highlights the nonlinear nature of ZnO. The field distributions of the doped structure are also considered and compared. We have focused on the 600-1200 nm wavelengths of the input beam, where nonlinear effects for ZnO are observed to be at their prime. It is observed that the mode distributions in the doped structure define solitary pulse propagation in itself.

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Advanced Materials Research (Volumes 403-408)

Pages:

3753-3757

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.403-408.3753

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Online since:

November 2011

Authors:

Rosmin Elsa Mohan, K.S. Sreelatha, M. Sivakumar, A. Krishnashree

Keywords:

Doped ZnO, Nonlinearity, Rectangular Waveguide, Solitons, Waveguide Modes

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References

[1] Robert W. Boyd, 'Applications of nonlinear fiber optics, Elsevier, Third ed.

Google Scholar

[2] H. Yamada, M. Shirane, T. Chu, H. Yokoyama, S. Ishida, Y. Arakawa: Jpn J. Appl . Phys 44 (2005) 6541.

DOI: 10.1143/jjap.44.6541

Google Scholar

[3] J.S. Levy, a . Gondarenko, M.A. Foster, A.C. Turner-Foster, A. L Gaeta, M. Lipson: Nat Photonics 4(2010) 37.

Google Scholar

[4] V. G . Ta'eed, M. Shokooh –Sarei, L. Fu, D.J. Moss, M. Rochette, I. Litter, B.J. Eggleton, Y. Ruan,B. Luther –Davies: Opt . Lett. 30 (2005)2900.

DOI: 10.1364/ol.30.002900

Google Scholar

[5] patents. com/us-7529460. html.

Google Scholar

[6] Optical Waveguide Theory; IEEE Transactionson Circuits and Systems, Vol CAS- 26, No: 12 , (1979).

Google Scholar

[7] A W Snyder, IEEE Trans , Microwave Theory Tech., vol. MTT-17, p.1138, (1969).

Google Scholar

[8] D. Gloge, Appl. Opt., vol 10, p . 2442, (1971).

Google Scholar

[9] C. Yeh, Advances in communications through light fibers, Advances in Communication Systems, vol. 4, Theory and Applications, New York: Academic (1975).

Google Scholar

[10] L. Eyges, P. Gianno, P. Wintersteiner, Modes of dielectric waveguides of arbitrary cross-section shapes', Appl. Opt, communicated and to be published.

Google Scholar

[11] Lianghong Yin, Q. Lin, Govind. P, Agrawal; Dispersion tailoring and soliton propagation in silicon waveguides, Vol . 31, No. 7/OPTICS LETTERS.

DOI: 10.1364/ol.31.001295

Google Scholar

[12] G.P. Agrawal, Nonlinear Fiber Optics, 4th ed. (Academic, 2001).

Google Scholar