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@Article{HasarBarKayKarErt:2015:InTrRe,
               author = "Hasar, Ugur Cem and Barroso de Castro, Joaquim Jos{\'e} and Kaya, 
                         Y. and Karacali, Tehvit and Ertugrul, M.",
          affiliation = "{University of Gaziantep} and {Instituto Nacional de Pesquisas 
                         Espaciais (INPE)} and {Bayburt University} and {Ataturk 
                         University} and {Ataturk University}",
                title = "Investigation of transmitted, reflected, and absorbed powers of 
                         periodic and aperiodic multilayered structures composed of 
                         bi-anisotropic metamaterial slab and conventional material",
              journal = "Photonics and Nanostructures - Fundamentals and Applications",
                 year = "2015",
               volume = "13",
                pages = "106--119",
                month = "Jan.",
             keywords = "Power analysis, Bi-anisotropic, Metamaterials, Conventional 
                         materials.",
             abstract = "In this study, we investigate transmitted, reflected, and absorbed 
                         powers in forward and backward directions of periodic and 
                         aperiodic multilayered structures composed of bi-anisotropic 
                         metamaterial (MM) slab and conventional material. Aperiodic 
                         multilayered structure is realized by a change in thickness of any 
                         bi-anisotropic MM slab or of any conventional material. From this 
                         analysis, we note the following key results. First, identical 
                         (non-identical) forward and backward transmitted (reflected and 
                         absorbed) powers are observed for the analyzed periodic and 
                         aperiodic multilayered structures due to reciprocity 
                         (reflection-asymmetry) of bi-anisotropic MM slabs. Second, 
                         thickness-resonance phenomenon of conventional materials produces 
                         some peaks in the transmitted powers of periodic multilayered 
                         structures aside from the resonance frequency region of 
                         bi-anisotropic MM slabs. Third, each thickness-resonance frequency 
                         splits into many frequencies upon increasing the number of 
                         sections of periodic multilayered structures (no splitting when 
                         number of periods is one). Fourth, while the effect of changing 
                         the thickness of any bi-anisotropic MM slab within the aperiodic 
                         multilayered structure has no considerable effect around the 
                         resonance region of bi-anisotropic MM slabs (resonance of 
                         resonating structures such as MM slabs does not change with 
                         thickness), the same change in thickness of the conventional 
                         material drastically alters forward/backward reflected and 
                         absorbed powers aside from the resonance region of bi-anisotropic 
                         MM slabs (thickness-resonance totally depends on the value of 
                         thickness of conventional materials). The outcomes presented here 
                         can be particularly useful for propagation-related applications 
                         requiring cascade connection of various MM slabs.",
                  doi = "10.1016/j.photonics.2014.12.003",
                  url = "http://dx.doi.org/10.1016/j.photonics.2014.12.003",
                 issn = "1569-4410",
             language = "en",
           targetfile = "hasar_investigation.pdf",
        urlaccessdate = "04 dez. 2020"
}


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