2 research outputs found
Enhanced self-collimation effect by low rotational symmetry in hexagonal lattice photonic crystals
In this study, we present the design of a photonic crystal (PC) structure
with a hexagonal lattice, where adjustments to the PC unit cell symmetry reveal
an all-angle self-collimation (SC) effect. By optimizing opto-geometric
parameters, such as the rotational angle of auxiliary rods and adjacent
distances, we analyze the SC property in detail, leveraging group velocity
dispersion (GVD) and third-order dispersion (TOD) characteristics. We also
investigate the relationship between symmetry properties and their influence on
dispersion characteristics. Through symmetry manipulation, we gain a
comprehensive understanding of the underlying mechanisms governing light
collimation and confinement in the proposed configurations. The PC structure
with a symmetry group exhibits all-angle SC effect within the range of
and normalized frequencies, with a
bandwidth of . Further breaking the symmetry,
transforming from to group symmetry, enhances the SC bandwidth to
and reveals the perfect linear equi-frequency
contours (EFC) at two different frequency bands: all angle SC between
and normalized frequencies in the 4th
transverse magnetic (TM) band and between and
in the 5th TM band. Additionally, we propose a
composite/hybrid PC structure resembling group symmetry, where two
auxiliary rods are replaced by rectangular photonic wires with the same
refractive index and width equal to the diameter of auxiliary rods. This hybrid
structure exhibits an all-angle SC effect with an operating bandwidth of
, displays near-zero GVD and TOD performance
and offers enhanced robustness against potential fabrication precision issues