Integrated optical filters are key components for high-capacity photonic networks with wavelength division multiplexing (WDM) near a wavelength of lambda_o = 1.55 µm (frequency f_o=193 THz). Integrateable optical filters, e.g., ring resonators in a silicon-on-silica technique, require a structural precision in the 10-nm range, while electron beam lithography has a practical resolution of only 30...50nm. Model experiments near f_m=10GHz need a much lower dimensional accuracy in the order of 10nm x f_o/f_x=0.2 mm, which can be easily achieved even with numerically controlled milling machines. We propose to investigate various periodic two-dimensional photonic crystal model structures at microwave frequencies for checking our design procedure. As a further benefit, we can measure the fields using electric or magnetic probes. The optical silica substrate is modeled by micro-fibre filled PTFE (teflon) with n²_PTFE = (1,48)²= 2.2 in the microwave case, the optical silicon waveguides are replaced with ceramic-filled PTFE having n²_cer= (3.3)²=10.8. Besides the modeling of periodic structures intended to be realized at optical frequencies, we plan to design photonic crystals for direct microwave use. We are especially interested in two-dimensional photonic bandgap structures for suppressing parasitic parallel plate modes which limit the bandwidth of planar microwave antenna arrays with optical feeder networks.

DFG Programme Priority Programmes

Subproject of SPP 1113:  Photonic Crystals

Participating Person Professor Dr. Kurt Busch