Temperature-independent silicon subwavelength grating waveguides | Zendy

Jens H. Schmid | Zendy; M. Ibrahim | Zendy; Pavel Cheben | Zendy; J. Lapointe | Zendy; Siegfried Janz | Zendy; P. Böck | Zendy; A. Densmore | Zendy; B. Lamontagne | Zendy; R. Ma | Zendy; Winnie N. Ye | Zendy; DanXia Xu | Zendy

AI Assistant Blog Pricing

Home ZAIA Blog

Open Access

Temperature-independent silicon subwavelength grating waveguides

Author(s) -

Jens H. Schmid,

M. Ibrahim,

Pavel Cheben,

J. Lapointe,

Siegfried Janz,

P. Böck,

A. Densmore,

B. Lamontagne,

R. Ma,

Winnie N. Ye,

DanXia Xu

Publication year - 2011

Publication title -

optics letters

Language(s) - English

Resource type - Journals

SCImago Journal Rank - 1.524

H-Index - 272

eISSN - 1071-2763

pISSN - 0146-9592

DOI - 10.1364/ol.36.002110

Subject(s) - materials science , silicon , optics , grating , waveguide , wavelength , silicon photonics , core (optical fiber) , optoelectronics , physics , composite material

We demonstrate, by experiment and numerical calculations, temperature-independent subwavelength grating waveguides with a periodic composite core composed of alternating regions of silicon and SU-8 polymer. The polymer has a negative thermo-optic (TO) material coefficient that cancels the large positive TO effect of the silicon. Measurements and Bloch mode calculations were carried out over a range of silicon-polymer duty ratios. The lowest measured TO coefficient at a wavelength of 1550 nm is 1.8×10(-6) K(-1); 2 orders of magnitude smaller than a conventional silicon photonic wire waveguide. Calculations predict the possibility of complete cancellation of the silicon waveguide temperature dependence.

The content you want is available to Zendy users.

Already have an account? Click here to sign in.

Having issues? You can contact us here

Accelerating Research