dc.description.abstract |
The study of light transport through disordered photonic structures has great significance in
understanding the fundamental light-matter interactions as they are crucial in developing various
optical functionalities. There are several important phenomena that are induced by the disordered
natural photonic nanostructures, such as antireflection, camouflage, antibacterial, and coloration.
This has motivated to design the structures with multifunctional optical properties or bio-inspired
photonic nanostructures. For instance, the gradient refractive index variation in these
nanostructures is a key factor for their antireflection characteristics, whereas the sharp tip of the
structures mechanically ruptures the bacterial cell wall result in their bactericidal activities. The
certain coloration in natural creatures arises either due to the long-range and short-range order and
mimicking such design on an artificial platform provides optimal light scattering features for
photonics-and energy-based applications.
In this thesis, we have primarily focused on light transport in two types of photonic structures,
namely the vertically aligned disordered silicon nanowires and the clusters of monodisperse
scatterers. The vertically aligned disordered silicon nanowire arrays synthesized using a facile and
cost-effective metal-assisted chemical etching method. We study the broadband omnidirectional
anti-reflectivity from vertically aligned disordered SiNWs of large aspect ratio. An aberration-free
micro-reflectivity setup equipped with an in-situ optical microscope is designed to measure
reflectivity from both the top and cross-sectional surface of the SiNWs samples. We have
measured the reflectivity as low as 5% irrespective of spatial-directions and the polarization of
incident light in a broad wavelength range. The polarization-and direction-independent near-zero
reflection of light constitutes the true two-dimensional omnidirectional anti-reflector.
Further, we discuss the estimation of the effective refractive index profile using the spatial- and
polarization-dependent reflectivity values along the nanowire length. We have found that the
gradient variation of the effective refractive index profile is tunable with nanowire length. The
transfer matrix method involving the estimated refractive index profiles is employed to corroborate
the measured reflectivity values. We have found that a disordered nanowire sample with an exponential refractive index profile along its length shows enhanced antireflection and light
trapping features. Moreover, we have also found the bactericidal activities of the nanowires, which
are very effective but lacking cell viability due to the use of hydrofluoric acid during the nanowire
fabrication. To overcome this limitation, we have used silicon nanopyramids which are
synthesized using a single step wet etching technique. The nanopyramid based antibacterial surface
offers better control over bacterial growth, chemical stability, and cell viability.
We have also studied the controlled light scattering in three-dimensional correlated disordered
photonic structures with short-range order. The samples possess clusters of monodisperse
scatterers, and their optical conductance shows a resonant frequency gap which is controllable with
the scatterers size and refractive index. The scattering model is designed based on the structural
morphology of the samples to validate the tunability of the frequency gap. The light transport
parameters such as scattering mean free path and transport free mean path is estimated using static
measurements. We have found that the photonic structures with short-range order can actively
modify the light scattering parameters in a specific wavelength range. Further, we have obtained
an anisotropic scattering regime in the range of frequency gap, which is a much sought-after goal
in photonic scattering systems, which is also in complete agreement with the theory. |
en_US |