Your search keyword '"Bahram Khalichi"' showing total 23 results

1. Multi-band light-matter interaction in hBN-based metasurface absorber

Author

Zahra Rahimian Omam, Bahram Khalichi, Ataollah Kalantari Osgouei, Amir Ghobadi, Ekmel Ozbay, Omam, Zahra Rahimian, Khalichi, Bahram, Osgouei, Ataollah Kalantari, Ghobadi, Amir, and Özbay, Ekmel

Subjects

Metasurfaces, Polar materials, Plasmon-phonon polaritons, Multi-band perfect absorbers

Abstract

Conference Name: International Conference on Electromagnetics in Advanced Applications (ICEAA) Date of Conference: 05-09 September 2022 This paper presents a multi-band metamaterial-based absorber using phononic two-dimensional (2D) material. The structure consists of a top hexagonal boron nitride (hBN) layer on an aluminum nanograting structure deposited on a dielectric slab waveguide and a thick metallic reflector forming an MIM (metal-insulator-metal) configuration. The proposed absorber exhibits a hyperbolic phonon polariton (HPPs) in hBN, surface plasmon (SP) modes in the spacer (ZnTe: zinc telluride), and Fabry-Perot resonances in the MIM configuration, resulting in five sharp, high absorption peaks in the mid-infrared (MIR) spectral range. The proposed multi-band absorber can be utilized in various applications, ranging from optical detection devices to multispectral thermoelectric volt.

Published

2022

2. Highly one-way electromagnetic wave transmission based on outcoupling of surface plasmon polaritons to radiation modes

Author

Bahram Khalichi, Zahra Rahimian Omam, Ataollah Kalantari Osgouei, Amir Ghobadi, Ekmel Ozbay, Khalichi, Bahram, Omam, Zahra Rahimian, Osgouei, Ataollah Kalantari, Ghobadi, Amir, and Özbay, Ekmel

Subjects

Asymmetric transmission, Long- and short-range surface plasmon polaritons, Diode-like behavior, Metasurface, Diffraction grating

Abstract

Conference Name: Antennas and Propagation Society International Symposium Date of Conference: 10-15 July 2022 Unidirectional transmission of electromagnetic waves has attracted great interest due to its wide modern optical applications. This study theoretically demonstrates a one-way transmissive optical device with a high-contrast forward-to-backward ratio at the near-infrared region. The polarization-independent optical diode-like mechanism is designed using a metasurface diffraction grating configuration with symmetry breaking property along the wave propagation in which the working principle is based on the excitation of surface plasmon modes at the interfaces of thin metallic interlayer and their coupling to the radiation modes.

Published

2022

3. A Transparent All-Dielectric Multifunctional Nanoantenna Emitter Compatible With Thermal Infrared and Cooling Scenarios

Author

Ekmel Ozbay, Hasan Kocer, Ataollah Kalantari Osgouei, Amir Ghobadi, Bahram Khalichi, Khalihi, Bahram, Ghobadi, Amir, Osgouei, Ataollah Kalantari, Koçer, Hasan, and Özbay, Ekmel

Subjects

Materials science, Photon, General Computer Science, thermal infrared applications, Infrared, Plasmonic structure, Effective radiated power, Grating, Thermal camouflage, Optics, General Materials Science, Black-body radiation, Absorption (electromagnetic radiation), Common emitter, Nanoantenna emitter/absorber, nanoantenna emitter/absorber, thermal camouflage, business.industry, General Engineering, Thermal infrared applications, Binary grating, TK1-9971, plasmonic structure, Computer Science::Programming Languages, Electrical engineering. Electronics. Nuclear engineering, business, Visible spectrum

Abstract

In modern thermal infrared applications, multi-spectral camouflage scenarios should be developed to mitigate the thermal signature of an object. In general, camouflage needs to be satisfied in two main optical ranges: visible, and infrared (IR). In the IR range, two main camera modes are deployed to detect the IR signature of an object: $i) $ short-wave IR (SWIR) cameras that detect the solar photons reflected off a surface, $ii) $ mid-wave IR (MWIR) and long-wave IR (LWIR) cameras that directly collect the blackbody photons emitted from a hot object. Therefore, in an ideal scheme to acquire a multi-spectral camouflage function with self-cooling capability, the object should have: $i) $ perfect absorption in the SWIR range, $ii) $ perfect reflection in the MWIR and LWIR ranges, $iii) $ perfect absorption and one-way transmission in non-transmissive IR (NTIR) window (to radiatively cool itself), and $iv) $ visible transparency (to keep background visual appearance intact and to minimize the heat build-up due to solar absorption). In this paper, an all-dielectric nanoantenna emitter design is developed to comply with all the above-mentioned requirements. The approach relies on the indium tin oxide (ITO) grating structures coated on a flexible and transparent substrate (polystyrene). The spectral behaviors of the proposed structure are obtained using both analytical and numerical approaches. The design has an absorption peak with 0.8 amplitude in the SWIR mode (for the backward and forward illuminations), while it shows average reflections $\simeq 0.7 $ in the MWIR and LWIR ranges for the forward illumination. The peak values of transmission and absorption within the NTIR window for the forward illumination are around 0.6 and 0.9, respectively. Meanwhile, the use of lossless materials within the visible range provides visible light transmission and minimizes the heat build-up due to solar absorption. In addition, the radiated power calculation model is utilized to demonstrate the low power detection on the IR cameras.

Published

2021

4. Near-Field-Based Preconditioning Technique in the Incomplete-Leaf MLFMA for Nonuniformly Discretized Electromagnetic Scattering Problems

Author

Bahram Khalichi, Ozgur Ergul, and Vakur B. Eruirk

Published

2021

5. Wavelength Selectivity in a Polarization-Insensitive Metamaterial-Based Absorber Consistent With Atmospheric Absorption Windows

Author

Ekmel Ozbay, Bahram Khalichi, Ebru Buhara, Ataollah Kalantari Osgouei, and Amir Ghobadi

Subjects

Physics, business.industry, Atmospheric wave, Surface plasmon, Metamaterial, Physics::Classical Physics, Polarization (waves), Low emissivity, Narrowband, Astrophysics::Solar and Stellar Astrophysics, Absorption (logic), Photonics, Atomic physics, business, Physics::Atmospheric and Oceanic Physics

Abstract

We propose a polarization-insensitive metamaterial-based absorber consistent with the atmospheric absorption windows. The proposed design realizes triple narrowband perfect absorptions, whose absorption peaks perfectly match the atmospheric absorption windows while maintaining low emissivity within the atmospheric windows of $\boldsymbol{3-5\mu \mathrm{m}}$ and $\boldsymbol{8-12\mu \mathrm{m}}$ .

Published

2021

6. Dual-Band Polarization Insensitive Metamaterial-Based Absorber Suitable for Sensing Applications

Author

Ekmel Ozbay, Bahram Khalichi, Ataollah Kalantari Osgouei, Ebru Buhara, and Amir Ghobadi

Subjects

Materials science, business.industry, Physics::Optics, Metamaterial, Physics::Classical Physics, Polarization (waves), Symmetry (physics), Narrowband, Broadband, Optoelectronics, Multi-band device, Photonics, business, Absorption (electromagnetic radiation)

Abstract

We propose a dual-band metamaterial perfect absorber to achieve a narrowband absorption response in the visible range and a broadband absorptive characteristic in the near-infrared region. Moreover, by increasing the in-plane symmetry of the metamaterial, the polarization insensitive and angle insensitive absorptive features are verified.

Published

2021

7. Thermally Tunable from Narrowband to Broadband Metamaterial-Based Nanoantenna Emitter

Author

Bahram Khalichi, Amir Ghobadi, Ataollah Kalantari Osgouei, Hasan Kocer, Ebru Buhara, and Ekmel Ozbay

Subjects

Narrowband, Materials science, business.industry, Broadband, Thermal, Metamaterial absorber, Physics::Optics, Metamaterial, Optoelectronics, Photonics, business, Phase-change material, Common emitter

Abstract

A thermally tunable nanoantenna emitter based on a hybrid design made of a metamaterial absorber and a phase change material is developed for thermal camouflage applications. The proposed design perfectly mimics the atmospheric windows to obtain invisibility within the operating range of thermal cameras.

Published

2021

8. Uncovering the non-radiative thermal characteristics of a passive radiative cooler under real operating conditions

Author

Hasan Kocer, Yilmaz Durna, Halil Isik, Mahmut Can Soydan, Bahram Khalichi, Amir Ghobadi, Hamza Kurt, Ekmel Ozbay, Koçer, Hasan, Durna, Yılmaz, Işık, Halil, Soydan, Mahmut Can, Khalichi, Bahram, Ghobadi, Amir, and Özbay, Ekmel

Subjects

Radiative and non-radiative heat transfer, Acoustics and Ultrasonics, Passive radiative cooling, Thermal analysis, Condensed Matter Physics, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials

Abstract

Passive radiative cooling (PasRadCool), which emits thermal energy from objects to deep cold space through atmospheric transparency, offers complementary and alternative green energy solutions for passive cooling of buildings, clothing, and renewable energy harvesting. Depending on the spectral emissive/absorptive properties of the unit under test (UUT), radiative heat exchanges occur between the UUT, atmosphere, and sun, while at the same time non-radiative heat exchange occurs. The performance of the PasRadCool is determined by the combined thermal and thermodynamic effects of both exchange mechanisms. Although the non-radiative heat exchange, which consists of conductive and convective processes to the outer surfaces of the UUT and the surrounding air fluid, is very sensitive to environmental changes, the actual performance is not fully determined since this feature is considered statically in many studies. Herein, we propose a method that reveals the non-radiative thermal characteristics of the PasRadCool under real operating conditions. With a photonic radiative cooler structure, which we manufacture as a proof of concept, we perform nighttime field test measurements in varying non-radiative thermal conditions. The proposed method extracts the time-dependent non-radiative heat transfer coefficient of the UUT as accurately as possible. We also confirm that our experimental result shows good agreement with both numerical and analytical methods. The proposed approach, which highlights the realistic thermal management of PasRadCool, is not specific to the circumstances of our study and can be applied to all PasRadCool situations with different geometry, material, and environmental conditions.

Published

2022

9. Adaptive thermal camouflage using sub-wavelength phase-change metasurfaces

Author

Zahra RahimianOmam, Amir Ghobadi, Bahram Khalichi, Ekmel Ozbay, Omam, Zahra Rahimian, Ghobadi, Amir, Özbay, Ekmel, and Khalichi, Bahram

Subjects

Phase-change materials, Acoustics and Ultrasonics, Wood’s anomaly resonance, Metasurface, Surface plasmon polaritons, Condensed Matter Physics, Thermal camouflage, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials

Abstract

Sub-wavelength metasurface designs can be used to artificially engineer the spectral thermal signature of an object. The real-time control of this emission can provide the opportunity to switch between radiative cooling (RC) and thermal camouflage functionalities. This performance could be achieved by using phase-change materials (PCMs). This paper presents a sub-wavelength dynamic metasurface design with the adaptive property. The proposed metasurface is made of vanadium dioxide (VO2) nanogratings on a silver (Ag) substrate. The design geometries are optimized in a way that both narrowband and broadband mid-infrared (MIR) emitters can be realized. At low temperatures, insulating VO2 nanogratings trigger the excitation of Fabry–Perot mode inside the grating and surface plasmon polaritons at the metal–dielectric interface with an emission peak located in the MIR region to maximize the RC performance of the design. As temperature rises, the PCM transforms into a metallic phase material and supports excitation of Wood’s anomaly and localized surface plasmon resonance modes. Accordingly, the thermal signature is adaptively suppressed.

Published

2022

10. Visible light metasurface for adaptive photodetection

Author

Ataollah Kalantari Osgouei, Amir Ghobadi, Bahram Khalichi, Rana Asgari Sabet, Onur Tokel, Ekmel Ozbay, Osgouei, Ataollah Kalantari, Ghobadi, Amir, Khalichi, Bahram, Sabet, Rana Asgari, Tokel, Onur, and Özbay, Ekmel

Subjects

Tunable color filter, Adaptive photodetection, Acoustics and Ultrasonics, Condensed Matter Physics, Semiconductor-based metasurfaces, Phase change materials, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials

Abstract

Semiconductor-based sub-wavelength metasurfaces are promising device platforms for the realization of optically thick and electrically thin photodetectors. Strong light–matter interactions in ultrathin film regions provide an opportunity to achieve near-unity absorption in dimensions comparable with carrier diffusion length and this, in turn, leads to an efficient collection of photogenerated carriers. Moreover, the use of phase change materials can provide real-time active tuning of optical responses of metasurface-based devices. In the first part of this paper, a tunable color filtering device is demonstrated using a metasurface design made of sub-wavelength antimony trisulphide (Sb2S3) grating placed on top of a continuous silver layer. Four distinct optical states can be acquired upon (a) the changes in the incident light polarization and (b) the phase transitions of Sb2S3. Numerical simulations and theoretical modeling data show that Fabry–Perot resonances are the driving phenomena when the proposed design is normally illuminated by an electromagnetic field with transverse electric polarization. In contrast, surface plasmon resonances are excited in transverse magnetic polarization. Furthermore, it is shown that the resonance wavelengths of the proposed design can be dynamically tuned using the geometrical parameters. Later, in the second part of the paper, adaptive photodetection is designed by integrating a 5 nm Sb2S3 layer as a collection layer into the structure. The proposed metasurface design provides light–matter interaction in the Sb2S3 layer and maximizes the photogenerated carriers’ collection efficiency. The optically thick and electrically thin adaptive photodetection offers an opportunity to design efficient active optoelectronic and photonic devices.

Published

2022

11. Diode like high-contrast asymmetric transmission of linearly polarized waves based on plasmon-tunneling effect coupling to electromagnetic radiation modes

Author

Ataollah Kalantari Osgouei, Amir Ghobadi, Bahram Khalichi, Ekmel Ozbay, Khalichi, Bahram, Ghobadi, Amir, Osgouei, Ataollah Kalantari, and Özbay, Ekmel

Subjects

High contrast, Materials science, Asymmetric transmission, Acoustics and Ultrasonics, Condensed matter physics, Linear polarization, Physics::Optics, Diffraction grating, Plasmon tunneling, Condensed Matter Physics, Surface plasmon polaritons, Electromagnetic radiation, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, Coupling (electronics), Transmission (telecommunications), Plasmon, Quantum tunnelling, Diode

Abstract

We present a narrow-band optical diode with a high-contrast forward-to-backward ratio at the near-infrared region. The design has a forward transmission of approximately $88\% $, and a backward one of less than $3\% $, yielding a contrast ratio of greater than $14.5\,$ dB at a wavelength of $1550\,$ nm. The structure is composed of a one-dimensional diffraction grating on top of a dielectric slab waveguide, both of which are made of silicon nitride (Si3N4), and all together are placed over a silver (Ag) thin film embedded on a dielectric substrate. Utilizing a dielectric-based diffraction grating waveguide on a thin silver layer leads to the simultaneous excitation of two surface plasmon modes known as long- and short-range surface plasmon polaritons (SPPs) at both interfaces of the metallic layer. The plasmon-tunneling effect, which is the result of the coupling of SPPs excited at the upper interface of the metallic layer to the radiation modes, provides a high asymmetric transmission (AT) property. The spectral response of the proposed high-contrast AT device is verified using both rigorous coupled-wave analysis as an analytical approach and finite difference time domain as a numerical one.

Published

2021

12. Active Tuning From Narrowband To Broadband Absorbers Using A Sub-Wavelength Vo2 Embedded Layer

Author

Hodjat Hajian, Amir Ghobadi, Andriy E. Serebryannikov, Ekmel Ozbay, Bahram Khalichi, Ataollah Kalantari Osgouei, Osgouei, Ataollah Kalantari, Hajian, Hodja, Khalichi, Bahram, Serebryannikov, Andriy E., Ghobadi, Amir, and Ozbay, Ekmel

Subjects

Permittivity, Materials science, Biophysics, Physics::Optics, Localized surface plasmon, 02 engineering and technology, 01 natural sciences, Biochemistry, Optical switch, 010309 optics, Narrowband, 0103 physical sciences, Absorption (electromagnetic radiation), Plasmon, Perfect absorber, Active tunable metamaterial, business.industry, Vanadium dioxide, Metamaterial, Resonance, 021001 nanoscience & nanotechnology, Wavelength, Plasmonics, Optoelectronics, Condensed Matter::Strongly Correlated Electrons, 0210 nano-technology, business, Biotechnology

Abstract

Metamaterial perfect absorbers (MPAs) with dynamic thermal tuning features are able to control the absorption performance of the resonances, providing diverse applications spanning from optical switches and filters to modulators. In this paper, we propose an MPA with diverse functionalities enabled by vanadium dioxide (VO2) embedded in a metal-dielectric plasmonic structure. For the initial design purpose, a silicon (Si) nanograting on a silver (Ag) mirror is proposed to have multiple resonant responses in the near infrared (NIR) region. Then, the insertion of a thin VO2 layer at the right position enables the design to act as an on/off switch and resonance tuner. In the insulator phase of VO2, in which the permittivity data of VO2 is similar to that of Si, a double strong resonant behavior is achieved within the NIR region. By increasing the temperature, the state of VO2 transforms from insulator to metallic so that the absorption bands turn into three distinct resonant peaks with close spectral positions. Upon this transformation, a new resonance emerges and the existing resonance features experience blue/red shifts in the spectral domain. The superposition of these peaks makes the overall absorption bandwidth broad. Although Si has a small thermo-optic coefficient, owing to strong light confinement in the ultrasmall gaps, a substantial tuning can be achieved within the Si nanogratings. Therefore, the proposed hybrid design can provide multi-resonance tunable features to cover a broad range and can be a promising strategy for the design of linearly thermal-tunable and broadband MPAs. Owing to the proposed double tuning feature, the resonance wavelengths exhibits great sensitivity to temperature, covering a broad wavelength range $$.$$ Overall, the proposed design strategy demonstrates diverse functionalities enabled by the integration of a thin VO2 layer with plasmonic absorbers.

Published

2021

13. Broadband Analysis Of Multiscale Electromagnetic Problems: Novel Incomplete-Leaf Mlfma For Potential Integral Equations

Author

Manouchehr Takrimi, Ozgur Ergul, Vakur B. Erturk, Bahram Khalichi, Khalichi, Bahram, Takrimi, Manouchehr, and Ertürk, Vakur B.

Subjects

education.field_of_study, Scattering, Computer science, Low-frequency breakdown, Population, Multilevel fast multipole algorithm (MLFMA), Potential integral equations (PIEs), Multiscale electromagnetic problems, Integral equation, Incomplete tree structures, Reduction (complexity), Tree structure, Broadband, Electrical and Electronic Engineering, Multipole expansion, Cluster analysis, education, Algorithm

Abstract

Recently introduced incomplete tree structures for the magnetic-field integral equation are modified and used in conjunction with the mixed-form multilevel fast multipole algorithm (MLFMA) to employ a novel broadband incomplete-leaf (IL) MLFMA (IL-MLFMA) to the solution of potential integral equations (PIEs) for scattering/radiation from multiscale open and closed surfaces. This population-based algorithm deploys a nonuniform clustering that enables to use deep levels safely and, when necessary, without compromising the accuracy resulting in an improved efficiency and a significant reduction for the memory requirements (order of magnitudes) while the error is controllable. The superiority of the algorithm is demonstrated in several canonical and real-life multiscale geometries.

Published

2021

14. Fast Solutions of Multiscale Electromagnetic Problems Using Potential Integral Equations

Author

Bahram Khalichi, Ozgur Ergul, and Vakur B. Erturk

Subjects

Electromagnetics, Computer science, Scattering, 020206 networking & telecommunications, 02 engineering and technology, Solver, Integral equation, Matrix (mathematics), Hardware_GENERAL, 0202 electrical engineering, electronic engineering, information engineering, Applied mathematics, Electric potential, Magnetic potential, Multipole expansion

Abstract

We present a full-wave electromagnetics solver to analyze multiscale scattering problems. The developed solver employs potential integral equations, which include both the electric current and the normal component of the magnetic vector potential as unknowns. These formulations are able to circumvent the low-frequency breakdown and related inaccuracy issues encountered when using electric- and magnetic-field integral equations. To analyze multiscale electromagnetic problems involving highly nonuniform discretizations, we solve the obtained matrix equations iteratively by employing a broadband multilevel fast multipole algorithm with incomplete-leaf tree structures. Accuracy and efficiency of the implementation are demonstrated on conical electromagnetic scattering problems.

Published

2020

15. A spectrally selective gap surface-plasmon-based nanoantenna emitter compatible with multiple thermal infrared applications

Author

Ataollah Kalantari Osgouei, Ekmel Ozbay, Bahram Khalichi, Amir Ghobadi, Osgouei, Ataollah Kalantari, Ghobadi, Amir, Khalichi, Bahram, and Özbay, Ekmel

Subjects

Thermal radiation management, Materials science, Thermal infrared, business.industry, Surface plasmon, Physics::Optics, Plasmonic structure, Wavelength selectivity, Plasmon, Solar absorber, Gap surface, Atomic and Molecular Physics, and Optics, Electronic, Optical and Magnetic Materials, Optics, Nanoantenna emitter, business, Common emitter

Abstract

Wavelength-selective nanoantenna emitters have attracted considerable attention due to their widespread applications ranging from thermal radiation management to thermophotovoltaics. In this paper, we design a wavelength-selective nanoantenna emitter based on the excitation of gap-surface plasmon modes using a metal–insulator–metal configuration (silicon dioxide (SiO2) sandwiched between silver (Ag) layers) for satisfying multiple infrared applications. The proposed design, which is called design I, realizes triple narrowband perfect absorptions at the resonance wavelengths of 1524nm,2279nm, and 6000nm, which perfectly match the atmospheric absorption bands while maintaining relatively low emissivity in the atmospheric transparency windows of 3-5 µm and 8-12 µm. Later, the functionality of design I is extended, which is called design II, to include a broadband absorption at the near-infrared region to minimize the solar irradiation reflection from the nanoantenna emitter. Finally, single- and three-layer graphene are introduced to provide a real-time tuning of the infrared signature of the proposed nanoantenna emitter (design II). It is also demonstrated that the three-layer graphene structure can suppress an undesired absorption resonance wavelength related to the intrinsic vibrational modes (optical phonons) of the SiO2 layer by 53.19% compared to 25.53% for the single-layer one. The spectral analysis of design I is validated using both analytical and numerical approaches where the numerical simulation domain is extended for the analysis of design II. The thermal characteristic analyses of design I and design II (without/with graphene layers) reveal that infrared signatures of the blackbody radiation are significantly reduced for the whole wavelength spectrum at least by 96% and 91% within a wide temperature ranging from room temperature to 500K, respectively.

Published

2021

16. Nano shell impact on Huygens’ metasurface dipolar resonances and optical response

Author

Hamza Kurt, Halil Isik, Ekmel Ozbay, Yilmaz Durna, Hasan Kocer, Bahram Khalichi, Kocer, Hasan, Işık, Halil, Durna, Yılmaz, Khalichi, Bahram, and Özbay, Ekmel

Subjects

Physics, Forward scatter, business.industry, Phase (waves), Shell (structure), Physics::Optics, Statistical and Nonlinear Physics, Polarization (waves), Aspect ratio (image), Electromagnetic radiation, Atomic and Molecular Physics, and Optics, Dipole, Optics, Nano, business

Abstract

Due to several advantages over conventional devices for the control of electromagnetic (EM) radiation, the demand for metasurface utilization based on artificially engineered micro and nanostructures is boosted, especially in new generation devices. Among the metasurfaces family, there has been a growing interest in Huygens’ metasurfaces that are easy to fabricate due to their lower aspect ratio compared to their counterparts and also provide alternative electromagnetic radiation control by tuning the dipolar electric and magnetic resonances. In this study, an all-dielectric Huygens’ metasurface consisting of the high-refractive-index nano shells embedded in the low-refractive-index environment is designed and extensively investigated numerically and analytically in the near-infrared spectrum. By simply tuning the nano shell inner radius, the effects on the dipolar resonances are unveiled specific to the proposed design. To assess the EM wave interactions in the designed Huygens’ metasurface, an analytical model based on the coupled discrete dipole approach is applied for selected distinct cases of the designed metasurface. It is shown that the spectral position of the dipolar resonances can be detuned or tuned simultaneously depending on the structural parameter of the meta-atoms arranged in a periodic array. This study sheds light on the physics and abilities of the nano shell structure as a Huygens’ metasurface for the potential applications of metasurface-based light–matter interaction including imaging and sensing.

Published

2021

17. Broadband Solutions Of Potential Integral Equations With Nspwmlfma

Author

Ozgur Ergul, Bahram Khalichi, Vakur B. Erturk, Khalichi, Bahram, and Ertürk, Vakur B.

Subjects

Physics, Scattering, Mathematical analysis, Low-frequency (LF) breakdown, 020206 networking & telecommunications, Potential integral equations (PIEs), 02 engineering and technology, Solver, Integral equation, Range (mathematics), Nondirective stable plane-wave MLFMA (NSPWMLFMA), Broadband, Fast solvers, 0202 electrical engineering, electronic engineering, information engineering, Electric potential, Electrical and Electronic Engineering, Broadband antennas, Multipole expansion

Abstract

In this communication, a mixed-form multilevel fast multipole algorithm (MLFMA) is combined with the recently introduced potential integral equations (PIEs), also called as the $\boldsymbol {A}$ - $\phi $ system, to obtain an efficient and accurate broadband solver that can be used for the solution of electromagnetic scattering from perfectly conducting surfaces over a wide frequency range including low frequencies. The mixed-form MLFMA uses the nondirective stable plane-wave MLFMA (NSPWMLFMA) at low frequencies and the conventional MLFMA at middle/high frequencies. Various numerical examples are presented to assess the validity, efficiency, and accuracy of the developed solver.

Published

2019

18. Mid-infrared adaptive thermal camouflage using a phase-change material coupled dielectric nanoantenna

Author

Ekmel Ozbay, Hasan Kocer, Ebru Buhara, Bahram Khalichi, Amir Ghobadi, Buhara, Ebru, Ghobadi, Amir, Khalichi, Bahram, Kocer, Hasan, and Özbay, Ekmel

Subjects

Materials science, Acoustics and Ultrasonics, business.industry, Vanadium dioxide, Mid infrared, Metamaterial, Dielectric, Condensed Matter Physics, Phase-change material, Thermal camouflage, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, Camouflage, Thermal, Nanoantenna emitter, Optoelectronics, Condensed Matter::Strongly Correlated Electrons, business, Mid-infrared, Thermal detection

Abstract

Recently, camouflage technology has attracted researchers’ attention in a large variety of thermal applications. As a special phase change material (PCM), vanadium dioxide (VO2) is an excellent candidate for the studies conducted on thermal camouflage technology. VO2 has a transition from the insulator phase to the metal phase with the increase of the temperature. With regards to this unique feature, VO2 can contribute dynamic properties to the camouflage design. In this paper, a PCM–dielectric based metamaterial mid-infrared adaptive thermal camouflage nanoantenna is designed to perfectly mimic the atmospheric windows. The adaptive property of the proposed structure is obtained by using an ultrathin VO2 interlayer embedded within the grating. The spectral responses of the structure are computed using the finite difference time domain method, and the invisibility of the structure is proved using power calculations in the different mid-infrared regions.

Published

2021

19. Correction to: Active Tuning from Narrowband to Broadband Absorbers Using a Sub‑wavelength VO2 Embedded Layer

Author

Ataollah Kalantari Osgouei, Ekmel Ozbay, Hodjat Hajian, Amir Ghobadi, Bahram Khalichi, and Andriy E. Serebryannikov

Subjects

Optics, Narrowband, Computer science, business.industry, Broadband, Biophysics, Mistake, Layer (object-oriented design), business, Biochemistry, Biotechnology, Sub wavelength

Abstract

The original version of this article unfortunately contained a mistake. The name of the fourth author is written reversely. The complete name of the fourth author is as follows: “Andriy E.” as the first name, while “Serebryannikov” is his last name. The original article has been corrected.

Published

2021

20. Solution Of Potential Integral Equations With Nspwmlfma

Author

Vakur B. Erturk, Ozgur Ergul, Bahram Khalichi, and Manouchehr Takrimi

Subjects

Physics, Wavelength, Field (physics), Scattering, Surface wave, Plane wave, Electric potential, Multipole expansion, Integral equation, Computational physics

Abstract

In this contribution, we present a numerical implementation of recently developed potential integral equations (PIEs) by using nondirective stable plane wave multilevel fast multipole algorithm (NSPWMLFMA). The proposed method is efficient and accurate to solve large scattering problems involving perfectly conducting bodies with geometrical details, which require dense discretizations with respect to the operating wavelength. Numerical results in the form of scattered field from various objects are provided to assess the accuracy and efficiency of PIEs solved using NSPWMLFMA.

Published

2018

21. Development of novel wideband H-plane horn antennas by employing asymmetrical slots based on SIW technology

Author

Ali Pourziad, Saeid Nikmehr, and Bahram Khalichi

Subjects

Patch antenna, Microstrip antenna, Engineering, Coaxial antenna, business.industry, Antenna measurement, Electronic engineering, Antenna factor, Electrical and Electronic Engineering, business, Monopole antenna, Antenna efficiency, Radiation pattern

Abstract

In this article, a novel wideband horn antenna based on substrate integrated waveguide (SIW) technology is proposed. Design procedure is explained in details. The designed antenna consists of asymmetric radiating slots. Microstrip line is used as a transition between the 50 Ω standard source and the proposed antenna. The proposed antenna is designed to operate from 25 to over 55 GHz which exhibits 75% fractional bandwidth. Peak gain of the proposed antenna varies between 1 and 4 dB in its operating band. In addition, simulated radiation performances show approximately fixed and omnidirectional radiation patterns at the range of the operating frequencies. Furthermore, whole of the proposed antenna is implemented only on a single layer substrate with dimensions of 10.4 mm × 23.65 mm × 1.6 mm. Performances of the proposed antenna have been simulated with two different commercial software. In order to verify the design procedure and simulation results, the redesigned antenna for operation around 14 GHz has been simulated, fabricated, and tested.

Published

2015

22. Designing Wideband Tapered-Slot Antennas: A novel method using SIW technology

Author

Bahram Khalichi, Ali Pourziad, Mahsa Ebrahimpouri, and Saied Nikmehr

Subjects

Reconfigurable antenna, Engineering, Directional antenna, business.industry, Impedance matching, Slot antenna, Condensed Matter Physics, Microstrip, Cutoff frequency, law.invention, law, Electronic engineering, Electrical and Electronic Engineering, Wideband, Antenna (radio), business

Abstract

In this article, a novel method for the design of wideband tapered-slot antennas (TSAs) using substrate-integrated waveguide (SIW) technology is proposed. The proposed procedure includes modeling of TSAs by step lines, which are terminated in intrinsic impedance of free space, along with applying the theory of small reflections. To provide insight into the radiation mechanism of the designed antennas, the method is discussed in detail. Employing the proposed method, an initial antenna is designed with a central frequency of 37.5 GHz. This antenna, which is implemented on a single-layer substrate, is compact in size and has satisfying radiation characteristics. It provides 75% fractional bandwidth from 25 to over 55 GHz, with the peak gain variations between 2 and 5 dB in its operating band. To further verify the design principle, the proposed antenna is redesigned for a central frequency of 14 GHz, and its prototype is fabricated. The comparison of the simulated and measured results confirms the accuracy of the proposed method.

Published

2015

23. RECONFIGURABLE SIW ANTENNA BASED ON RF-MEMS SWITCHES

Author

Bahram Khalichi, and Ali Pourziad, and Saeid Nikmehr

Subjects

Reconfigurable antenna, Waveguide (electromagnetism), Radiation, Materials science, Null (radio), Acoustics, Condensed Matter Physics, law.invention, Radiation pattern, Planar, law, SMA connector, Radio frequency, Electrical and Electronic Engineering, Antenna (radio), Computer Science::Information Theory

Abstract

In this article, a novel compact reconfigurable antenna based on substrate integrated waveguide (SIW) technology is introduced. The geometry of the proposed antennas is symmetric with respect to the horizontal center line. The electrical shape of the antenna is composed of double H-plane SIW based horn antennas and radio frequency micro electro mechanical system (RF-MEMS) actuators. The RF-MEMS actuators are integrated in the planar structure of the antenna for reconfiguring the radiation pattern by adding nulls to the pattern. The proper activation/deactivation of the switches alters the modes distributed in the structure and changes the radiation pattern. When different combinations of switches are on or off, the radiation patterns have 2, 4, 6, 8, . . . nulls with nearly similar operating frequencies. The attained peak gain of the proposed antenna is higher than 5 dB at any point on the far field radiation pattern except at the null positions. The design procedure and closed form formulation are provided for analytical determination of the antenna parameters. Moreover, the designed antenna with an overall dimensions of only 63.6 × 50 mm2 is fabricated and excited through standard SMA connector and compared with the simulated results. The measured results show that the antenna can clearly alters its beams using the switching components. The proposed antenna retains advantages of low cost, low cross-polarized radiation, and easy integration of configuration.

Published

2013