Modal fields of anisotropic channel waveguides

R. A. Steinberg; T. G. Giallorenzi

doi:10.1364/JOSA.67.000523

Journal of the Optical Society of America
Vol. 67,
Issue 4,
pp. 523-533
(1977)
•https://doi.org/10.1364/JOSA.67.000523

Modal fields of anisotropic channel waveguides

R. A. Steinberg and T. G. Giallorenzi

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R. A. Steinberg and T. G. Giallorenzi, "Modal fields of anisotropic channel waveguides," J. Opt. Soc. Am. 67, 523-533 (1977)

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Abstract

We present an approximate analysis of the model fields and dispersion relations of anisotropic dielectric waveguides of rectangular cross section. We initially assume that the dielectric tensor is diagonal in both the guiding and substrate regions of the channel, with a step discontinuity at their interface. Off-diagonal elements in the dielectric tensor are then accomodated by means of coupled mode theory; continuous transverse variation of the dielectric tensor is taken into account by adapting a heuristic technique due to Miller. We have found that the anisotropy may act to decouple orthogonally polarized components of the field, resulting in almost-linearly-polarized modes for many cases of practical interest. We have also considered the coupling of energy between two such channel waveguides running parallel to one another.

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ν	_F(ν)	G⁽^ν⁾
2	k_ytan(k_yb + δ) − γ_c	$\frac{∊_{y}}{∊_{z}} (\frac{k_{0}^{2} ∊_{y c} - k_{x}^{2}}{k_{0}^{2} ∊_{y} - k_{x}^{2}}) k_{y} tan (k_{y} b + δ) - \frac{∊_{y c}}{∊_{z c}} γ_{c}$
3	k_xtank_xa − γ_x	$\frac{∊_{x}}{∊_{z}} (\frac{k_{0}^{2} ∊_{x s} - k_{y}^{2}}{k_{0}^{2} ∊_{x} - k_{y}^{2}}) k_{x} tan k_{x} a - \frac{∊_{x s}}{∊_{z s}} γ_{x}$
4	k_ytanδ + γ_s	$\frac{∊_{y}}{∊_{z}} (\frac{k_{0}^{2} ∊_{y s} - k_{x}^{2}}{k_{0}^{2} ∊_{y} - k_{x}^{2}}) k_{y} tan δ + \frac{∊_{y s}}{∊_{z s}} γ_{s}$

	K_x	Γ_x	K_y	Γ_s	Γ_c
E^x modes	$\frac{k_{x}}{∊_{x}}$	$\frac{γ_{x}}{∊_{x s}}$	k_y	γ_s	γ_c
E^y modes	k_x	γ_x	$\frac{k_{y}}{∊_{z}}$	$\frac{γ_{s}}{∊_{z s}}$	$\frac{γ_{c}}{∊_{z c}}$

ν	_F(ν)	G⁽^ν⁾
2	k_ytan(k_yb + δ) − γ_c	$\frac{∊_{y}}{∊_{z}} (\frac{k_{0}^{2} ∊_{y c} - k_{x}^{2}}{k_{0}^{2} ∊_{y} - k_{x}^{2}}) k_{y} tan (k_{y} b + δ) - \frac{∊_{y c}}{∊_{z c}} γ_{c}$
3	k_xtank_xa − γ_x	$\frac{∊_{x}}{∊_{z}} (\frac{k_{0}^{2} ∊_{x s} - k_{y}^{2}}{k_{0}^{2} ∊_{x} - k_{y}^{2}}) k_{x} tan k_{x} a - \frac{∊_{x s}}{∊_{z s}} γ_{x}$
4	k_ytanδ + γ_s	$\frac{∊_{y}}{∊_{z}} (\frac{k_{0}^{2} ∊_{y s} - k_{x}^{2}}{k_{0}^{2} ∊_{y} - k_{x}^{2}}) k_{y} tan δ + \frac{∊_{y s}}{∊_{z s}} γ_{s}$

	K_x	Γ_x	K_y	Γ_s	Γ_c
E^x modes	$\frac{k_{x}}{∊_{x}}$	$\frac{γ_{x}}{∊_{x s}}$	k_y	γ_s	γ_c
E^y modes	k_x	γ_x	$\frac{k_{y}}{∊_{z}}$	$\frac{γ_{s}}{∊_{z s}}$	$\frac{γ_{c}}{∊_{z c}}$

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Equations (99)

Journal of the Optical Society of America