Thesis Type: Doctorate
Institution Of The Thesis: Gazi University, Fen Bilimleri Enstitüsü, Turkey
Approval Date: 2021
Thesis Language: Turkish
Student: BUKET AKIN
Supervisor: Şemsettin Altındal
Open Archive Collection: AVESIS Open Access Collection
Abstract:
Dielectric metamaterials rationally engineered in both bulk and quasi-infinite planar fashions
with optical properties beyond natural materials have emerged as promising platforms for
developing resonant architectures with sub-wavelength dimensions. The main criterion that
distinguishes all-dielectric metamaterials from their plasmonic counterparts is that they
exhibit negligible losses in the infrared and visible spectral regions, possessing an immense
potential to be employed in developing ultradense and efficient devices. Advances in the
nanofabrication and design of dielectric metamaterials enabled the miniaturization of
photonic metadevices for coming generation technologies. In particular, dielectric�metamaterial coatings possess strategic applications such as high-resolution imaging and
thermal camouflage in diverse technologies through controlling the characteristic
reflection/transmission responses. In this study, the design, fabrication, and characterization
of Al2O3/Ge/ITO/Soda Lime Glass stack meta-absorbers consisting of dielectric layers to
provide broadband absorption of mid-infrared (MWIR) and long-infrared light (LWIR) are
presented. The structure was produced by coating with an e-beam thermal evaporation
system, one of the highly developed microfabrication techniques, sequentially without
vacuum breaking. Through computational investigations and experimental assessments, the
geometric parameters of the metastructure were judiciously selected, where the absorbance
of over ~92% was achieved in the conducted analyses. To mechanically understand the
properties of these customized all-dielectric meta-absorbers, we performed extensive
numerical calculations to investigate the effect of the thickness of the used Al2O3 layer on
the medium and LWIR absorption performance. Notably, the projected meta-absorber is
polarization-insensitive and performs consistently over a wide range of incidence angles.
Key Words : All-dielectric metamaterials, multilayer artificial media, meta
absorbers, mid and long-wave infrared.