Complex s-Plane Modeling and 2D Characterization of the Stochastic Scattering Loss in Symmetric Dielectric Slab Waveguides Exhibiting Ergodic Surface-Roughness With an Exponential Autocorrelation Function

The symmetric dielectric slab waveguide serves as an important canonical structure for the high-speed high-bandwidth optical and opto-electronic silicon-on-insulator interconnects. A stochastic model of propagation loss, due to electromagnetic wave scattering with surface-roughness of the nano-scale...

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Bibliographic Details
Published in:IEEE access 2021, Vol.9, p.92326-92344
Main Author: Zadehgol, Ata
Format: Article
Language:English
Subjects:
Amplitudes
Autocorrelation functions
Complex analysis
Correlation
Design optimization
Electromagnetic radiation
Electromagnetic waveguides
ergodic
Ergodic processes
Exact solutions
exponential autocorrelation
Optical interconnects
Optical surface waves
Optical waveguides
opto-electronic and optical interconnects
Optoelectronics
pole/residue
Roughness
stationary
stochastic
Stochastic models
Stochastic processes
Surface roughness
Surface waves
symmetric dielectric slab waveguides
Two dimensional models
Upper bounds
Wave propagation
Wave scattering
Waveguides
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Summary:The symmetric dielectric slab waveguide serves as an important canonical structure for the high-speed high-bandwidth optical and opto-electronic silicon-on-insulator interconnects. A stochastic model of propagation loss, due to electromagnetic wave scattering with surface-roughness of the nano-scale waveguide excited at frequencies in the 100s of THz, provides useful insights for analysis and design optimization of optical interconnects. In this work, we propose an analytic solution for the stochastic scattering integral based on contour integration of the exponential autocorrelation function in the complex s-plane that improves performance at larger autocorrelation length values, compared to previous works. An expression is proposed for computing the upper-bound value of scattering loss. Results show that the proposed 2D formulation offers reasonable correlation against data from experimental measurements of loss by previous investigators, while several discrepancies are noted compared to previous 2D models. An expression is proposed for the transverse magnetic (TM) modal field amplitude, and several discrepancies in the transverse electric (TE) modal amplitudes are noted compared to previous works. A method is proposed for computation of the effective index (and propagation constant) for arbitrary cladding that improves convergence of the Newton search method, and it is compared to two other methods. Background discussions include the stochastic theory and assumptions that lead to the stationary and ergodic treatment of the surface-roughness, extension of the ensemble-average and time-average to the spatial domain, and effective thickness due to the Goos-Hänchen shift.
ISSN:2169-3536
2169-3536
DOI:10.1109/ACCESS.2021.3092635