Title :
Concentration profile calculation for buried ion-exchanged channel waveguides in glass using explicit space-charge analysis
Author :
Hazart, Jerome ; Minier, V.
Author_Institution :
Groupement d Electromagnetisme Exp. et d Optoelectr., Meylan, France
fDate :
4/1/2001 12:00:00 AM
Abstract :
Ionic conductivity inhomogeneity and its relation to space charge is analyzed in the case of a two-ion exchange for channel waveguide fabrication in optical glass. The space-charge evolution equation is derived and discussed in a general binary ion exchange context. This leads to an efficient algorithm which computes current-density nonuniformity in the field-assisted burying of ion-exchanged waveguides. The algorithm exhibits excellent agreement with the classic potential equation perturbed by nonhomogeneous ionic conductivity, and is appreciably faster. We show that the homogeneous current-density assumption is inaccurate for the calculation of the burying depth and waveguide size in the case of a realistic glass with nonlinear ionic diffusivity
Keywords :
current density; integrated optics; ion exchange; ionic conductivity; optical fabrication; optical glass; optical waveguide theory; space charge; binary ion exchange context; buried ion-exchanged channel waveguides; channel waveguide fabrication; classic potential equation; concentration profile calculation; current-density nonuniformity; efficient algorithm; explicit space-charge analysis; field-assisted burying; glass; homogeneous current-density assumption; ion-exchanged waveguides; ionic conductivity inhomogeneity; nonhomogeneous ionic conductivity; nonlinear ionic diffusivity; space-charge evolution equation; two-ion exchange; waveguide size; Conductivity; Fiber nonlinear optics; Glass; Nonlinear equations; Optical device fabrication; Optical waveguide theory; Optical waveguides; Particle beam optics; Silver; Voltage;
Journal_Title :
Quantum Electronics, IEEE Journal of
