Thermal tuning of silicon-based one-dimensional photonic bandgap structures

## Abstract In this paper, we analyze finite one‐dimensional photonic crystals in which the layers in the primitive cell follow a pseudonoise sequence pattern. In this analysis, the layers are composed of two different materials, but the organization of the layers in the primitive cell is varied. T

## Abstract Antenna systems based on some improved metallic photonic bandgap (MPBG) structures are introduced. A useful modification is introduced by replacing each wire in a two‐dimensional MPBG structure by a chain of many identical conducting elements of a certain shape. Each such chain forms an

Photonic crystals consist of regularly arranged dielectric scatterers of dimensions on a wavelength scale, exhibiting band gaps for photons, analogous to the case of electrons in semiconductors. Using electrochemical pore formation in n-type silicon, we fabricated photonic crystals consisting of air

## Abstract An antenna based on a three‐dimensional metallic photonic bandgap (MPBG) structure consisting of many parallel metallic short wires is considered. An explicit method is introduced to calculate the radiation pattern for such an antenna system. The explicit method is verified numerically