Multi-bit graphene-based bias-encoded metasurfaces for real-time terahertz wavefront shaping: From controllable orbital angular momentum generation toward arbitrary beam tailoring

Rouhi, Kasra; Rajabalipanah, Hamid; Abdolali, Ali

doi:10.1016/j.carbon.2019.04.034

Cited by 94 publications

(69 citation statements)

References 66 publications

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“…As in the case of a single ribbon, we first treat the equation for J y . However, the interaction between ribbons, manifested in the periodic Green's function (12), leads to an important modification of the approximation (5). For sub-wavelength arrays where k 0 D 1, a lengthy calculation presented in the appendix shows that…”

Section: Scattering From An Infinite Array Of Ribbonsmentioning

confidence: 99%

“…Consider the Green function (12). The Hankel function is written as were the integration is carried out over the path shown on page 916 of [33] in the complex θ plane.…”

Section: Appendix Amentioning

confidence: 99%

“…This tunability provides additional flexibility in the design of diverse functionalities. Therefore, numerous graphene-based applications have been proposed from microwave to terahertz regions [5], [6], [7], [8], [9], [10], [11], [12] Under an external magnetic bias, the surface conductivity of graphene becomes a tensor, and it will also have non-reciprocal properties [13]. These extraordinary properties make graphene a promising material for many novel applications, such as isolators [14], nonreciprocal couplers [15], optical modulators [16], and Faraday rotators [17], in the terahertz regime.…”

Section: Introductionmentioning

confidence: 99%

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Analytical and rigorous method for analysis of an array of magnetically-biased graphene ribbons

Rahmanzadeh¹,

Rejaei²,

Memarian³

et al. 2019

Opt. Express

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A sheet of graphene under magnetic bias attains anisotropic surface conductivity, opening the door for realizing compact devices such as Faraday rotators, isolators and circulators. In this paper, an accurate and analytical method is proposed for a periodic array of graphene ribbons under magnetic bias. The method is based on integral equations governing the induced surface currents on the coplanar array of graphene ribbons. For subwavelength size ribbons subjected to normally incident plane waves, the current distribution is derived leading to analytical expressions for the reflection/transmission coefficients. The results obtained are in excellent agreement with full-wave simulations and predict resonant spectral effects that cannot be accounted for by existing semi-analytical methods. Finally, we extract an analytical, closed form solution for the Faraday rotation of magnetically-biased graphene ribbons. In contrast to previous studies, this paper presents a fast, precise and reliable technique for analyzing magnetically-biased array of graphene ribbons, which are one of the most popular graphene-based structures.

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Section: Scattering From An Infinite Array Of Ribbonsmentioning

confidence: 99%

“…Consider the Green function (12). The Hankel function is written as were the integration is carried out over the path shown on page 916 of [33] in the complex θ plane.…”

Section: Appendix Amentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Analytical and rigorous method for analysis of an array of magnetically-biased graphene ribbons

Rahmanzadeh¹,

Rejaei²,

Memarian³

et al. 2019

Opt. Express

View full text Add to dashboard Cite

show abstract

“…Recent years have witnessed a clear tendency toward achieving multiple contour beams using fully planar metasurface‐based devices with a lighter weight and lower cost compared to the solid reflectors [ 6 ] and bulky metamaterials. [ 7 ] Metasurfaces, engineered arrays of artificially patterned microelements on a flat surface, have recently emerged as a flourishing concept which attracts tremendous interest because of providing peculiar routes to manipulate the phase, [ 8–10 ] polarization, [ 11 ] amplitude, [ 12–14 ] transversal shape, [ 15,16 ] and trajectory [ 17–20 ] of the electromagnetic (EM) fields. Since Capasso's group introduced the generalized laws of refraction/reflection in 2011, [ 21 ] this 2D version of metamaterials has inspired many exceptional and modern devices, typically in the field of antennas and antenna accessories.…”

Section: Introductionmentioning

confidence: 99%

Flexible Manipulation of Emitting Beams Using Single‐Aperture Circularly Polarized Digital Metasurface Antennas: Multi‐Beam Radiation toward Vortex‐Beam Generation

Nadi

Rajabalipanah

Cheldavi

et al. 2020

Advcd Theory and Sims

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As the technological demands for multiple‐input multiple‐output communication systems increasingly grow, there is a critical need for the next generation of multi‐beam radiators. The concept of single‐feed compact phase‐encoded metasurface antennas is introduced, the radiation specifications of which can be flexibly manipulated to provide circularly‐polarized single‐, dual‐, quad‐beam far‐field patterns, a circularly‐polarized optical angular momentum‐carrying beam, and a circularly‐polarized quasi‐omnidirectional emission. With a small footprint area at f = 5.8 GHz, the proposed circularly polarized coding metasurface antenna (CPCMA) consists of several radiating meta‐atoms with 2‐bit excitation phases of 0, π/2, π, and 3π/2. Compared with conventional antenna arrays, the center‐to‐center distance of the coding elements is noticeably reduced, where periodic boundary conditions have been employed to analyze the inter‐element coupling effects. A low‐cost and simple corporate feed network is also designed to implement the required coding mask of each CPCMA type. To verify the performance of the proposed CPCMA, a prototype is fabricated and measured. Proof‐of‐concept experiments demonstrate excellent agreement with numerical simulations and theoretical predictions. This constructs a bridge between conventional arrays and digital metasurfaces, providing a powerful host for the next generation of multi‐beam circularly polarized radiators.

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“…In another context, metasurfaces are known as two-dimensional versions of the metamaterial family [23] at subwavelength scales which cover a broad scope of applications due to their strong interactions with light and ease of fabrication [24]. They provide prominent abilities for polarizing [25][26][27][28], absorbing [29][30][31][32], channeling [33][34][35][36][37][38][39][40], and processing [41][42][43][44] waves, especially within optical frequencies. Several analytical frameworks have been recently developed to synthesize metasurfaces at microscopic to macroscopic scales such as impedance/ admittance matrices [45,46], generalized sheet transition conditions (GSTCs) by susceptibility tensors [47,48], polarizability tensors [49][50][51], and local complex scattering parameters [39,[52][53][54].…”

Section: Introductionmentioning

confidence: 99%

Parallel integro-differential equation solving via multi-channel reciprocal bianisotropic metasurface augmented by normal susceptibilities

et al. 2019

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Analog optical signal processing has dramatically transcended the speed and energy limitations accompanied with its digital microelectronic counterparts. Motivated by recent metasurface's evolution, the angular scattering diversity of a reciprocal passive bianisotropic metasurface with normal polarization is utilized in this paper to design a multi-channel meta-computing surface, performing multiple advanced mathematical operations on input fields coming from different directions, simultaneously. Here, the employed ultra-thin bianisotropic metasurface computer is theoretically characterized based on generalized sheet transition conditions and susceptibility tensors. The operators of choice are deliberately dedicated to asymmetric integro-differential equations and image processing functions, like edge detection and blurring. To clarify the concept, we present several illustrative simulations whereby diverse wave-based mathematical functionalities have been simultaneously implemented without any additional Fourier lenses. The performance of the designed metasurface overcomes the nettlesome restrictions imposed by the previous analog computing proposals such as bulky profiles, asserting only single mathematical operation, and most importantly, supporting only the even-symmetric operations for normal incidences. Besides, the realization possibility of the proposed metasurface computer is conceptually investigated via picturing the angular scattering behavior of several candidate meta-atoms. This work opens a new route for designing ultra-thin devices executing parallel and accelerated optical signal/image processing.

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Multi-bit graphene-based bias-encoded metasurfaces for real-time terahertz wavefront shaping: From controllable orbital angular momentum generation toward arbitrary beam tailoring

Cited by 94 publications

References 66 publications

Analytical and rigorous method for analysis of an array of magnetically-biased graphene ribbons

Analytical and rigorous method for analysis of an array of magnetically-biased graphene ribbons

Flexible Manipulation of Emitting Beams Using Single‐Aperture Circularly Polarized Digital Metasurface Antennas: Multi‐Beam Radiation toward Vortex‐Beam Generation

Parallel integro-differential equation solving via multi-channel reciprocal bianisotropic metasurface augmented by normal susceptibilities

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