Title :
Athermal High-Index-Contrast Waveguide Design
Author :
Ye, Winnie N. ; Michel, Jurgen ; Kimerling, Lionel C.
Author_Institution :
Microprocessing/Microphotnics Center, Massachusetts Inst. of Technol., Cambridge, MA
fDate :
6/1/2008 12:00:00 AM
Abstract :
We present generalized design rules for athermal performance and materials compatibility in high-index-contrast (HIC) waveguides. Thermal stability of integrated photonic devices is one critical limitation in the development of commercially viable integrated optoelectronic circuits. Thermooptically neutral designs are achieved by choosing a cladding material whose thermooptic coefficient is opposite to that of the waveguide core. We derive analytical expressions of athermal conditions for both symmetric and asymmetric channel waveguide structures. The equations apply to general HIC systems such as silicon-on-insulator and SiN-based structures.
Keywords :
cladding techniques; integrated optoelectronics; optical waveguides; thermal stability; athermal performance; channel waveguide structures; cladding material; high index contrast waveguide; integrated photonic devices; materials compatibility; thermal stability; thermooptic coefficient; Optical interferometry; Optical ring resonators; Optical waveguides; Polarization; Polymers; Refractive index; Silicon; Temperature distribution; Temperature sensors; Thermal stresses; Athermal design; high-index-contrast (HIC); polymer cladding; temperature control; thermooptic effects;
Journal_Title :
Photonics Technology Letters, IEEE
DOI :
10.1109/LPT.2008.922338
