Browsing by Subject "Absorber"

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    High-conductivity silicon based spectrally selective plasmonic surfaces for sensing in the infrared region
    (Institute of Physics Publishing, 2017) Gorgulu, K.; Gok, A.; Yilmaz, M.; Topalli K.; Okyay, Ali Kemal
    Plasmonic perfect absorbers have found a wide range of applications in imaging, sensing, and light harvesting and emitting devices. Traditionally, metals are used to implement plasmonic structures. For sensing applications, it is desirable to integrate nanophotonic active surfaces with biasing and amplification circuitry to achieve monolithic low cost solutions. Commonly used plasmonic metals such as Au and Ag are not compatible with standard silicon complementary metal-oxide-semiconductor (CMOS) technology. Here we demonstrate plasmonic perfect absorbers based on high conductivity silicon. Standard optical lithography and reactive ion etching techniques were used for the patterning of the samples. We present computational and experimental results of surface plasmon resonances excited on a silicon surface at normal and oblique incidences. We experimentally demonstrate our absorbers as ultra-low cost, CMOS-compatible and efficient refractive index sensing surfaces. The experimental results reveal that the structure exhibits a sensitivity of around 11 000 nm/RIU and a figure of merit of up to 2.5. We also show that the sensing performance of the structure can be improved by increasing doping density.
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    Highly-doped silicon based photonic devices for mid-infrared light absorption
    (2017-07) Görgülü, Kazim
    Electromagnetic wave absorbers have the potential to enable important applications in the mid-infrared wavelength range such as thermal imaging and infrared spectroscopy. The choice of absorbing material has signi cant implications for the ultimate utility of any photonic device or structure. So far, traditional metals are employed as common absorbing materials, especially in metamaterial designs. However, many of these metals react with the atmosphere or water, limiting their utility for a wide range of applications. There are many materials, other than conventional metallic components, that exhibit lossy properties and provide advantages in device performance, design exibility, fabrication, integration, and tunability. Here, we investigate highly doped silicon as an e cient absorbing material for the mid-infrared regime. The absorption is achieved by the free carriers in the silicon which can be spectrally tuned by controlling its carrier concentration. Most of the resonant absorbers su er from narrow operating absorption waveband. A common approach is to use multiple resonance centers to increase bandwidth. However, the number of resonators combined within the same unit cell is limited. We propose highly doped silicon based absorbers with a patterned silicon-on-insulator substrate that provide enhanced bandwidth without compromising absorption performance. Broadband absorption is achieved by the combined e ects of bulk absorption, and vibrational and plasmonic absorption resonances. Moreover, we investigate black silicon concept for mid-infrared regime. The structures investigated unveil wideband and e cient absorbers. An analytical description of the wave propagation in black silicon texture is presented, showing agreement with the experiment and the computational analysis. Some other applications, such as selective thermal emitters and detectors, and bio-chemical and refractive index sensors, require narrow absorption bands. Plasmonic absorbers typically have narrow resonance bands and they can be utilized in highly sensitive detection schemes. Traditional metals are common materials for these applications. However, apart from their fabrication challenges, they have extremely large, negative permittivity. This feature of metals signi cantly limits their plasmonic mode con nement in the mid-infrared regime. In this regime, highly doped silicon is a promising plasmonic material for sensing applications owing to its suitable plasma frequency. Here, we demonstrate plasmonic perfect absorbers based on high conductivity silicon and investigate refractive index sensing performance of the absorbers. Keywords:
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    The left hand of electromagnetism : metamaterials
    (2010) Alıcı, Kamil Boratay
    Metamaterials are artificial periodic structures whose electromagnetic response is solely dependent on the constituting unit cells. In the present thesis, we studied unit cell characteristics of metamaterials that has negative permeability and permittivity. We investigated negative permeability medium elements, especially in terms of their electrical size and resonance strength. Experimental and numerical study of µ-negative (MNG) materials: multi split ring resonators (MSRRs), spiral resonators (SRs) and multi-spiral resonators are presented. The resonance frequency of the structures is determined by the transmission measurements and minimum electrical size of λ0/17 for the MSRRs and of λ0/82 for the SRs observed. We explain a method for tuning the resonance frequency of the multi-split structures. We investigated scalability of MNG materials and designed a low loss double negative composite metamaterial that operates at the millimeter wave regime. A negative pass-band with a peak transmission value of -2.7 dB was obtained experimentally at 100 GHz. We performed transmission based qualitative effective medium theory analysis numerically and experimentally, in order to prove the double negative nature of the metamaterial. These results were supported by the standard retrieval analysis method. We confirmed that the effective index of the metamaterial was indeed negative by performing far field angular scanning measurements for a metamaterial prism. Moreover, we illuminated the split-ring resonator based metamaterial flat lens with oblique incidence and observed from the scanning experiments, the shifting of the beam to the negative side. The first device was a horn antenna and metamaterial lens composite whose behavior was similar to Yagi-Uda antenna. We numerically and experimentally investigated planar fishnet metamaterials operating at around 20 GHz and 100 GHz and demonstrated that their effective index is negative. The study is extended to include the response of the metamaterial layer when the metamaterial plane normal and the propagation vector are not parallel. We also experimentally studied the transmission response of a one dimensional rectangle prism shaped metamaterial slab for oblique incidence angles and confirmed the insensitivity of split-ring resonator based metamaterials to the angle of incidence. After the demonstration of complete transmission enhancement by using deep subwavelength resonators into periodically arranged subwavelength apertures, we designed and implemented a metamaterial with controllable bandwidth. The metamaterial based devices can be listed under the categories of antennas absorbers and transmission enhancement. We studied electrically small resonant antennas composed of split ring resonators (SRR) and monopoles. The electrical size, gain and efficiency of the antenna were λ0/10, 2.38 and 43.6%, respectively. When we increased the number of SRRs in one dimension, we observed beam steerability property. These achievements provide a way to create rather small steerable resonant antennas. We also demonstrated an electrically small antenna that operates at two modes for two perpendicular polarizations. The antenna was single fed and composed of perpendicularly placed metamaterial elements and a monopole. One of the metamaterial elements was a multi split ring resonator and the other one was a split ring resonator. When the antenna operates for the MSRR mode at 4.72 GHz for one polarization, it simultaneously operates for the SRR mode at 5.76 GHz, but for the perpendicular polarization. The efficiencies of the modes were 15% and 40% with electrical sizes of λ/11.2 and λ/9.5. Finally, we experimentally verified a miniaturization method of circular patch antennas. By loading the space between the patch and ground plane with metamaterial media composed of multi-split ring resonators and spiral resonators, we manufactured two electrically small patch antennas of electrical sizes λ/3.69 and λ/8.26. The antenna efficiency was 40% for the first mode of the multi-split ring resonator antenna with broad far field radiation patterns similar to regular patch antennas. We designed, implemented, and experimentally characterized electrically thin microwave absorbers by using the metamaterial concept. The absorbers consist of i) a metal back plate and an artificial magnetic material layer; ii) metamaterial back plate and a resistive sheet layer. We investigated absorber performance in terms of absorbance, fractional bandwidth and electrical thickness, all of which depend on the dimensions of the metamaterial unit cell and the distance between the back plate and metamaterial layer. As a proof of concept, we demonstrated a λ/4.7 thick absorber of type i), with a 99.8% absorption peak along with a 8% fractional bandwidth. We have also demonstrated experimentally a λ/4.7 and a λ/4.2 thick absorbers of type ii), based on SRR and MSRR magnetic metamaterial back plates, respectively. The absorption peak of the SRR layout is 97.4%, while for the MSRR one the absorption peak is 98.4%. We conveyed these concepts to optical frequencies and demonstrated a metamaterial inspired absorber for solar cell applications. We finalized the study by a detailed study of split ring resonators at the infrared and visible band. We studied i) frequency tuning, ii) effect of resonator density, iii) shifting magnetic resonance frequency by changing the resonator shape, iv) effect of metal loss and plasma frequency and designed a configuration for transmission enhancement at the optical regime. By using subwavelength optical split ring resonator antennas and couplers we achieved a 400-fold enhanced transmission from a subwavelength aperture area of the electrical size λ2 /25. The power was transmitted to the far field with 3.9 dBi directivity at 300 THz.
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    Wideband 'black silicon' for mid-infrared applications
    (Institute of Physics Publishing, 2017) Görgülü, Kazım; Yılmaz, Mehmet; Topallı, Kağan; Okyay, Ali Kemal
    In this paper, we investigate the absorption of mid-infrared light by low resistivity silicon textured via deep reactive ion etching. An analytical description of the wave propagation in black silicon texture is presented, showing agreement with the experiment and the computational analysis. We also study the dependence of absorption spectrum of black silicon structure on the electrical conductivity of silicon substrate. The structures investigated unveil wideband, all-silicon infrared absorbers applicable for infrared imaging and spectroscopy with simple CMOS compatible fabrication suitable for optoelectronic integration.