Transmission through Surface Disordered Waveguides and Nanowire as Drastic Influence on Coherent Scattering
DOI:
https://doi.org/10.48165/Keywords:
Transmission, surface disordered, waveguides, roughness, boundary-scatteringAbstract
We have studied transmission through surface disordered waveguides in general and a solid basis. Our results showed that desired transmission properties on a waveguide through the roughness of its boundaries can be obtained. This surface scattering approach predicted that how mode specific scattering lengths in waveguides depend on the details of system’s surface roughness. It was shown that previously neglected
square-gradient scattering mechanism and predicted that this new scattering mechanism has to be considered together with the conventional amplitude scattering mechanism. Square gradient scattering is related to higher order terms in the disorder strength it can be the major scattering mechanism in system with modest disorder. Surface scattering theory is for long range correlations, which seems to restrict its applicability to very long waveguides. We have extended this surface scattering theory to short, individual waveguides. We found that an observed shift of the amplitude scattering gap could be attributed to the nonvanishing disorder strength. We also found that short wave lengths can exhibit effects predicted for systems with long range correlations leading to drastic changes in their transmission properties. The obtained results were compared with previously obtained results of theoretical and experimental works and were found in good agreement.
References
. Khurgin. J.B., Dikmelik. Y., Liu. P.Q., Hoffman. A.J., Escarra. M.D., Franz. K.J. and Gmachl. C. F. (2009), Appl. Phys. Lett. 94, 091101.
. Han. M.Y., Ozyilmaz. B., Zhang. Y. and Kim. P., (2007), Phys. Rev. Lett. 98, 206805. [3]. Evaldson. M., Zozoulenko. I.V., Hu. H. and Heinzel. T., (2008), Phys. Rev. B, 78, 161407. [4]. Jenke. T., Geltenbort. P., Lemmel. H. and Abele. H., (2011), Nat. Phys. 7, 468. [5]. Hochbaum. A. I., Chen. R., Delgado. R.D., Liang. W., Garnett. E.C., Najarian. M., Majumdar. A, Yang. P. (2008), Nature (London), 45, 163.
. Frisk. G.V. (1994), Ocean and Seabed Acoustics: A Theory of wave propagation (Pearson Education, Prentice Hall, Upper Saddle River, N. J., 1994).
. Chaikina. E.I., Stepanov. S, Navarrete. A.G., Mendez. E. R. and Leskova. T.A., (2005), Phys. Rev. B, 71, 085419.
. Maker. A.J., Armani. A.M. (2011), Opt. Lett. 36, 3729.
. Gan. L., and Li. Z, (2012), Front. Optoelectron 5, 21.
. Maradudin. A.A. (2011), Structured surfaces as optical Metamaterials, (Cambridge University Press, Cambridge, New York, 2011).
. Maire. G., Drsek. F, Girad. J, Giovannini. H., Talneau. A, Konan. D., Delkebir. K., Chaument. P.C. and Sentenac. A. (2009), Phys. Rev. Lett. 102, 213905.
. Zhao W., Ding. J.W. (2010). Europhys. Lett. 89, 57005.
