Dyadic Green ’ s Function for Multilayered Planar, Cylindrical, and Spherical Structures with Impedance Boundary Condition

The integral equation (IE) method is one of the efficient approaches for solving electromagnetic problems, where dyadic Green ’ s function (DGF) plays an important role as the Kernel of the integrals. In general, a layered medium with planar, cylindrical, or spherical geometry can be used to model different biomedical media such as human skin, body, or head. Therefore, in this chapter, different approaches for the derivation of Green ’ s function for these structures will be introduced. Due to the recent great interest in two-dimensional (2D) materials, the chapter will also discuss the generalization of the technique to the same structures with interfaces made of isotropic and anisotropic surface impedances. To this end, general formulas for the dyadic Green ’ s function of the aforementioned structures are extracted based on the scattering superposition method by considering field and source points in the arbitrary locations. Apparently, by setting the surface conductivity of the interfaces equal to zero, the formulations will turn into the associated problem with dielectric boundaries. This section will also aid in the design of various biomedical devices such as sensors, cloaks, and spectrometers, with improved functionality. Finally, the Purcell factor of a dipole emitter in the presence of the layered structures will be discussed as another biomedical application of the formulation.


Introduction
Planarly, cylindrically and spherically layered media have been widely used to model the human skin, body, or head. In particular, a rectangular slab is proposed to model and analyze skin temperature distribution [1]. Moreover, in the multilayered skin model, three stacked layers are exploited to simulate the performance of the epidermis, dermis, and sub-cutis parts of the skin [2]. In other research, a planarly layered medium has been proposed as the simplified human body model by considering the impact of skin, fat, and muscle in the electromagnetic performance [3]. Cylindrical-shaped equivalent phantom of the skin is alternatively used to characterize the interactions between an antenna and the human body [4]. For a more precise investigation, multilayered cylinders are proposed to model a biological system with different tissues [5]. Considering spherical geometrics, the interactions of a in the dielectric model, it is necessary to compute the special functions of the cylindrical and spherical coordinates with complex arguments, which requires the implementation of specific algorithms for their effective calculation [24], while in the impedance boundary condition method, the surface conductivity of graphene appears as a coefficient for special functions. Third, in the dielectric model, the thickness of the graphene layer is considered to be about 0.335 nm, which is often very small compared to other geometrical parameters and makes the convergence of the analytical functions slow [25]. Also, if the goal is using the dielectric model in numerical methods, it is necessary to use a dense mesh for the equivalent dielectric of the graphene that is not optimal in terms of time and memory [26].
Applying the graphene surface conductivity model for the derivation of the Green's function has been considered in recent years. For example, for the graphene sheet under electric bias, the dyadic Green's function is derived by the Hertzian potential and plane-wave expansion methods and the corresponding integrals are solved with the saddle point method [27,28]. Also, the method is expanded for the analysis of graphene with tensor surface conductivity which can be used to analyze graphene with magnetic bias or spatial dispersion. Romberg's integration procedure is proposed for the numerical solution of the resulting integrals [29]. In another research, the analysis of the electric dipole in the proximity of the parallel plate waveguide with graphene walls is studied by extracting the Green's function and calculating the spontaneous emission. It is found that symmetric and asymmetric plasmonic modes lead to a sharp increase in this parameter [30]. As another instance, a point source is taken into account in the vicinity of the infinite cylinder with graphene cover and it is observed that by changing the distance of the source from the cylinder as well as changing the chemical potential of the graphene layer, the Fano resonances can be controlled [31]. In this chapter, the dyadic Green's function of various planar, cylindrical, and spherical geometries with impedance boundary conditions will be calculated using the scattering superposition method. Specifically, we have focused on the graphene material due to its wide range of applications. Apparently, another 2D material can be considered by replacing the graphene surface conductivity with the surface conductivity of the desired material. The presented formulas can be potentially sued to design various biomedical devices. Moreover, by approaching the surface impedance to zero, these structures can be potentially used to investigate the interaction of the human body with different electromagnetic sources. For the Green's function calculation of complex media in different coordinates using vector wave functions, the reader is referred to [32][33][34][35].

Surface conductivity of graphene material under different conditions
Graphene is a two-dimensional material made of carbon atoms and can be considered in the solution of Maxwell's equations using surface conductivity boundary condition [23]. Depending on the geometrical and optical conditions, graphene surface conductivity can be isotropic or anisotropic. The purpose of this section is to provide an overview of the graphene surface conductivity under different conditions (electric bias, magnetic bias, and spatial dispersion) and for different geometries (continuous or patterned sheets).
It should be noted that graphene material is mainly synthesized through four methods, including 1) mechanical exfoliation of highly ordered pyrolytic graphite (HOPG), 2) the epitaxial growth of graphene on silicon carbide (SiC), 3) the reduction of graphene oxide, and 4) chemical vapor deposition (CVD) technique. The comparison of these methods in terms of quality and the fabricated area is provided in Table 1 [36].
In this regard, a monolayer graphene film with metallic electrodes is transferred to a high impedance surface (HIS) which is realized by the printed circuit board (PCB) technology at microwave frequencies. The measurement is conducted in a small microwave chamber [37]. In another research in the same spectrum, an infrared laser is used to etch the CVD grown graphene sheet with predefined periodicity and later investigate the absorption of the designed structure inside a rectangular waveguide [38]. The electron beam lithography is another approach used for pattering the graphene sheet for enhanced light matter interaction [39]. Moreover, a transparent graphene millimeter wave absorber constructed by multiple transfer-etch processing is characterized by reflectometery technique at 140 GHz [40]. Also, CVD-grown graphene is used to enhance the sensitivity of the surface-enhanced Raman spectroscopy (SERS)-based chemical sensor. The measurement is done using a Raman spectrometer at the laser wavelength of 785 nm (red) [41]. In another sensor chip, DNA is hybridized to the graphene-based substrate under UV light with the wavelength of 260 nm. In this sensor, the atomic force microscopy (AFM) is used to ensure the continuity and uniformity of the synthesized graphene, and Raman characterization is used to investigate its quality and the number of layers [42].

Graphene material under electric bias
When a graphene sheet is under electric bias, its surface conductivity is isotropic and can be approximately calculated by using Kubo's formulas as [43]: In the above equations, T is the temperature, μ c is the chemical potential of graphene, ℏ is the reduced Planck's constant, K B is the Boltzmann's constant, and ω is the angular frequency. At low-THz frequencies, the inter-band contribution of the surface conductivity can be neglected. Also, the graphene layer can be modeled as a dielectric with very low thickness δ and equivalent dielectric constant ε ¼ 1 À i σ ωε 0 δ [22]. Note that in the above equations, graphene is assumed to be in the linear region, otherwise, other terms proportional to 1=ω 3 and 1=ω 4 should be added respectively for the frequency range of ℏω < 2μ c and ℏω ≥ 2μ c [44].
To increase the light-matter interaction of graphene material, the nano-pattering method has been proposed [45]. The surface conductivity of the periodic graphene Comparison of the quality and area of synthesized graphene using different techniques [36].
elements under the electric bias is also isotropic. For the square patches shown in Figure 1(a), by considering the periodicity of D 0 and the air gap distance of g, closed-form surface impedance (inverse of the surface conductivity) is as [47]: The effective surface conductivity of periodic graphene elements with arbitrary pattern can be measured or extracted using the parameter retrieval method through full-wave simulation [48]. It should be noted that for computing the electric field required for each considered chemical potential, approximate equations can be derived as [49]: where, λ 1 ¼ 0:3677 and λ 2 ¼ 0:5010. For the chemical potentials in the range of [À1,1] eV, the required bias fields are in the order of several volts per nanometer, which can be implemented practically [29].
The surface conductivity of densely packed graphene strips, as illustrated in Figure 1(b), is anisotropic and can be approximated in the form of a diagonal tensor using the effective medium formulation as [50]: In the above equations, W and L are the width and periodicity of the strips, respectively. Also, σ is the surface conductivity of graphene under electric bias, and σ c is the static conductivity of the surface. Two very important properties of this environment are the existence of near-zero surface conductivity and hyperbolic dispersion region with the potential applications in 2D lens structures and the spontaneous emission enhancement of the dipole emitters [50,51].

Graphene sheet with spatial dispersion effects
When the graphene sheet is placed on a substrate with a high dielectric constant, its surface conductivity is a tensor in which the elements depend on the wave propagation constant in the structure. This is called the spatial dispersion effect and the associated formulae for calculating surface conductivity are [29]: The parameters σ, α, and β are extracted for an unbiased sheet μ c ¼ 0 ð Þthorough perturbation theory [29]. The resulting equations are valid for the electrically biased sheet μ c 6 ¼ 0 ð Þ, as well [52].

Graphene sheet under magnetic bias
When a graphene sheet is under magnetic bias, its surface conductivity is also a tensor. The diagonal elements of this tensor are equal and the off-diagonal elements are opposite in sign defined as [53].
where σ 0 ¼ 2e 2 τ πℏ 2 k B T ln 2 cosh μ c 2k B T and ω c ¼ . The approximate formulas for the calculation of the surface impedance of the square graphene elements under magnetic bias, shown in Figure 1(a), are as follows [54]: where the electrically biased patterned elements with arbitrary shapes, the parameter retrieval method can be used under the applied magnetic bias [55]. Given the discussion of the above three sections, it is observed that assuming the surface conductivity of graphene as: All items expressed above can be extracted as a special case.

Analysis of graphene-based structures using dyadic Green's function
Dyadic Green's functions for the planarly, cylindrically, and spherically layered structures with graphene interfaces will be derived in this section. To this end, the boundary conditions of the continuity and discontinuity of tangential electric and magnetic fields are respectively satisfied regarding the considered surface conductivity model for the graphene.

Graphene-based planarly layered media
This section aims to obtain dyadic Green's functions for planar structures with graphene boundaries. This problem can be solved either in the rectangular or cylindrical coordinates. In the first sub-section, a graphene sheet with the tensor surface conductivity boundary condition (TSCBC) is considered and its dyadic Green's function is calculated in the rectangular coordinates. In this case, the anisotropy of the surface impedance causes the coupling of the transverse electric (TE) and transverse magnetic (TM) fields. As a result of coupling, the number of unknown coefficients in the expansion of the dyadic Green's function is increased concerning the electrically biased sheet. In the second part of this section, a graphene-dielectric stack with an arbitrary number of layers is investigated considering the electric bias for the graphene sheets. This problem is solved in the cylindrical coordinates to simplify the calculation of the resulted Sommerfeld integrals.

Graphene sheet with the tensor surface conductivity boundary condition
The purpose of this section is to obtain the dyadic Green's function of a graphene sheet with the tensor surface conductivity in the interface of half-spaces, as shown in Figure 2(a). The constitutive parameters of the top and bottom regions are considered as (ε 1 , μ 1 ) and (ε 2 , μ 2 ), respectively. Without losing the generality of the problem, the source is assumed to be in the first environment and the graphene boundary is considered in z = 0 interface. Dyadic Green's function of this structure will be calculated using the scattering superposition method. For this purpose, the Green's function in each region of the problem is written in the form of the Green's function in the absence and presence of structure. Thus [23]: where G  (a) Graphene sheet with the tensor surface conductivity boundary condition at the interface of half-spaces [46] and (b) graphene-dielectric stack.
Also, G e0 is the free-space Green's function which can be computed using the G m method as: , it can be readily found that: The parameters k x , k y , and k z are the wavenumbers in x, y, and z directions, respectively, and k j shows the wavenumber for j = 1, 2. These parameters are not independent and are related to each other via k z ¼ AE The vector wave function M represents the electric field of TE modes and the vector wave function N shows the electric field of the TM waves. In the structure under consideration, the anisotropy of surface conductivity leads to the coupling of TE and TM fields. Therefore [56]: The unknown coefficients a 1 , a 0 1 , b 1 , b 0 1 , a 2 , a 0 2 , b 2 , and b 0 2 will be obtained by applying the boundary conditions. Using the self and mutual orthogonality of the vector wave functions, the above equations can be divided into two systems of equations, each with four unknown coefficients. The boundary conditions on the electric and magnetic Green's functions respectively state that: After applying the above boundary conditions and removing the coupling effect from the tangential components of the electric field, and by defining, the unknown coefficients of the TE waves, a 1 ¼ Δ TE , can be obtained as [46]: Δ TM , it can be shown: Other unknown coefficients can be obtained using decoupling equations in [46]. To validate the obtained coefficients, the structure of Figure 1(a) consisting of square patches with D 0 = 5 μm, g = 0.5 μm, μ c = 0.5 eV and τ = 0.5 ps with plane wave illumination is considered under electric and magnetic biases. Since Green's function coefficients are the same as reflection and transmission coefficients of the plane wave, the results of Green's function are compared with the results of the circuit model as [54]: Figure 3 shows the magnitude of the transmission coefficient by considering the electric bias for the graphene layer. The results of the two methods are identical, Figure 3. The magnitude of the transmission coefficient for the graphene nano-patch with the parameters D 0 = 5 μm, g = 0.5 μm, μ c = 0.5 eV, and τ = 0.5 ps [46]. and because of the absence of electromagnetic coupling under electric bias, the transmission coefficient due to mutual coupling is zero. In Figure 4 the same results are illustrated for the applied magnetic bias of 0.5 Tesla. There is good agreement in the magnitude and phase of the transmission coefficient in the abovementioned two methods. Also, by finding the poles of the coefficients, the electromagnetic wave propagation constants for the electrically and magnetically biased graphene sheets can be obtained which are in full agreement with [28, 57], respectively. The correctness of the extracted coefficients confirms the validity of the dyadic Green's function formulation.

Graphene-dielectric stack
Dyadic Green's function for an N-layer dielectric environment has been previously formulated using the scattering superposition method [58]. In this section, the above equations are extended to the environment with the electrically biased graphene boundaries, as shown in Figure 2(b). The graphene boundary can be either continuous or periodically patterned as discussed in section 2. To start the analysis, the layers are numbered by starting from the top layer, and an arbitrary field point i and source point j are assumed. The problem is solved in the cylindrical coordinates. Since the cylindrical wave functions are discussed in detail in the next section, they are not mentioned here. The dyadic Green's function can be expanded as [58]: . The boundary condition on the tangential components of the magnetic field yields: By re-writing the coefficients as a matrix: the outgoing and incoming reflection and transmission coefficients can be defined and used to extract the recursive relations. The coefficients for M 0 sources are: The coefficients for N 0 sources are: The superscripts H and V respectively denote TE and TM sources. Also, subscripts F and P are used to show the incoming and outgoing waves, respectively. The procedure of extracting the unknown coefficients using (34)-(41) is discussed in [58]. To validate the proposed formulas, a parallel plate waveguide with graphene walls is considered. To extract the characteristic equation using the proposed formulations, it is necessary to force the denominator of the coefficients equal to zero. For this three-layer medium:  (1) and (3) are the same, and also defining h ¼ iωμ 1 σ, for the H coefficients it can be concluded that: This procedure is repeatable for V sources. Also, to calculate the reflection coefficient from a multilayer structure, it is necessary to consider the field and source points in region 1. In this case, the only non-zero coefficient in Green's function expansion is B 11 M,N coefficient representing the plane wave reflection coefficient from the multilayer structure.

Graphene-based cylindrical structures
In this section, the dyadic Green's function of a cylindrical structure with the tensor surface conductivity boundary condition will be extracted. Later, different examples of guiding and scattering problems are provided to investigate the validity of the formulation. In general, in cylindrical structures, TE and TM modes are coupled, which leads to the complexity of mathematical relations. Therefore, the generalization of the formulation to the multilayered cylinders is not considered here. Note that graphene sheets can be wrapped around cylindrical particles due to the presence of van der Waals force [59]. For this purpose, tape-assist transfer under micromanipulation and spin-coating methods are proposed [60].

Dyadic Green's function for a cylinder with tensor surface conductivity boundary condition
The dyadic Green's function of the single-layer cylinder with the tensor surface conductivity boundary condition, as considered in Figure 5., will be extracted in the following. The interior region of the cylinder is made of dielectric material and its cover is considered as a full tensor surface conductivity. To solve the problem, the vector wave functions are defined as [23]: In the above equations, Z m is the cylindrical Bessel function in the inner layer and the cylindrical Hankel function in the outer layer, both with the orders of m. The wavenumber in the radial direction is μ and the wavenumber along the length is h. The free-space Green's function in the cylindrical coordinates is [23]: Figure 5.
(a) A monolayer cylinder with a 2D cover with the tensor surface conductivity boundary condition and (b) its special cases constructed by densely packed strips and square nano-patches [61].
In the cylindrical coordinate system, TE and TM modes are coupled and the expansion of the fields are [23].
where A η , B η , C η , and D η are the unknown coefficients of the DGF expansion in region 1. Also, a ξ , b ξ , c ξ , and d ξ are DGF expansion coefficients in the region 2. The boundary condition on the tangential components of the magnetic Green's function is given by [61]:r By applying the above-mentioned boundary condition along with the boundary condition regarding the continuity of the electric Green's function to (47)-(48), the system of equations to determine the unknown coefficients can be obtained as: where: Nullifying the determinant of the matrices (50)-(51) for m = 0, each of the above matrices can be separated as the multiplication of: For the graphene shell under magnetic bias, both matrices in (50)-(51) result in the following equation for the propagation constant of hybrid TE and TM waves: Which is in agreement with [57]. Also, the total scattering cross-section (TSCS) of a graphene-coated cylinder with the parameters a = 50 μm, ε 2 = 2.4, τ = 1 ps, μ c = 0.25 eV under electric bias is calculated for both TE and TM polarizations in Figure 6, and compared with the results of the CST2017 software package. As can be seen, both methods have resulted in the same results.
As another example, the densely packed graphene strips with the parameters L = 420 nm, W = 400 nm, μ c = 0.5 eV, and τ = 1 ps are considered around the dielectric cylinder as in Figure 5. It is assumed that the strips are wrapped around a hollow cylinder with the radius of a = 50 μm. Figure 7 shows the TSCS of this structure for the magnetic biases with the strength in the range of 20-40 T. As observed, by increasing the magnetic bias, the resonant frequency of the surface plasmons blue shifts. The associated planar structure behaves as a hyperbolic metasurface [62]. Under locally flat consideration of the curvature, this structure can also be considered as a hyperbolic medium. In the cylindrical geometries, hyperbolic meta-surfaces can be obtained using graphene-dielectric stacks [63]. The advantage of this hyperbolic structure is its two-dimensional nature and reconfigurability. It is also demonstrated that covering the surface of nanotubes with the hyperbolic meta-surface increases the interaction of the light with dipole emitters [64].
Finally, as Figure 5(b) illustrates, graphene-based square patches around the cylinder are considered under magnetic bias. Geometrical and optical parameters are as follows: τ = 1 ps, g = 0.5 μm, and D = 0.5 μm and the TSCS is illustrated in Figure 8. for B 0 = 0 T and B 0 = 10 T. As can be seen, by changing the magnetic bias, the optical state changes from the maximum scattering to the minimum scattering. Such capability has recently been proposed by using a phase change material for switching between these two situations [65]. In this structure, the operating frequency can also be adjusted by changing the electric bias of graphene.  It is essential to note that in the cylindrical structures, the spatial domain Green's function consists of an integral on the real axis. Due to the existence of poles in the integration path, the integration path is usually deformed into a triangular shape. Also, a common method for calculating the spatial domain Green's function is the generalized pencil of function (GPOF) method in which the Green's function is expanded in terms of the complex exponential functions [66]. The unknowns can be found via the algorithm provided in [67]. Also, as mentioned earlier, the dyadic Green's function of the graphene-based multilayered cylindrical structures will not be considered here. For calculating the scattering cross-section of graphene-based multilayer cylindrical structures, a simple approach based on the transfer matrix method (TMM) is proposed that will be suitable for establishing novel optical devices [68,69].

Graphene-based spherically layered medium
In this section, a multi-layered spherical structure with the graphene boundaries is considered and its Green's function is extracted by assuming different locations for the source and observation points. The relationship between the Green's function expansion coefficients and the modified Mie-Lorentz coefficients is exhibited to discuss how to solve the scattering problems using the Green's function. Scattering analysis of graphene-based layered structures is of great importance in the design of novel optical devices [70]. Finally, the procedure for calculating the Purcell factor is considered as an important application. Instances of experimentally realized graphene-coated spherical particles can be found in [71,72], where improved template method and hydrothermal method are proposed for the synthesis. Also, transmission electron microscopy (TEM) and field emission scanning electron microscopy (FE-SEM) are used for characterization.

Dyadic Green's function of a graphene-based spherically layered structure
Let us consider an N-layer spherical medium with the graphene boundaries as shown in Figure 9. The purpose of this section is to compute the dyadic Green's function of this structure with the assumption of arbitrary locations for the field and source points. For this purpose, the Green's function in each layer is expanded in terms of vector wave functions with unknown coefficients. These functions are calculated using the scalar wave function of [74]: φ mn r, θ, ϕ ð Þ¼z n k p r À Á P m n cos θ ð Þe imϕ (55) where z n : ð Þ represents the spherical Bessel or Hankel functions of order n and P m n : ð Þ is the associated Legendre function with degree n and order m. It can be readily shown that: The above vector functions are self and mutually orthogonal. This feature will be used to decouple the equation when computing the unknown coefficients.
As mentioned earlier, in the scattering superposition method, the dyadic Green's function is written as the sum of the free-space and scattering Green's functions. The free-space Green's function is related to the source in an infinite homogeneous medium while the scattering Green's function is due to the source in the presence of the layered medium. The expansion of the Green's function for the spherical structure with N concentric layers, assuming that the source and field points are respectively located in the desired layers with the labels p and q, can be written as [23] The free-space Green's function can be obtained using the residue theorem as [23]:Ĝ 0e r, r 0 ð Þ ¼ Àrr Moreover, scattering Green's function in each layer can be expanded as [75]: where functions. To determine the delta functions related to the source terms, free-space Green's function can be used. For q = 1 (external layer), the source functions related to the second criterion of the free-space Green's function is used. Also, for q = N (internal layer) the source functions related to the first criterion should be used. In the middle layers, a linear combination of different source functions must be used. It should be noted that by using the addition theorem in Legendre functions, the internal series in the Green's function expansion can be eliminated [11]. To select the number of terms required for the convergence of the external series, the conditions of the problem must be considered. In the other words, in the structures whose electrical size is very much smaller than that of the wavelength, the term n = 1 is sufficient for the convergence [76]. Also, in the case where the distance between the source and observation points is large, the series can be truncated in the number Otherwise, the convergence of the series is weak, and a large number of terms in the range of 20 k 0 R 1 should be considered. In this case, the series acceleration techniques will be highly efficient in terms of computational efficiency [77,78].
Boundary conditions on tangential components of electric and magnetic Green's functions in the interface of two adjacent layers are [

T H
The source dependency is the same in all of the above Green's functions and can be simplified from both sides of the equation. It is observed that the equation is converted into the equation resulting from the Mie analysis of the spherically layered structures. By directly starting from the Mie-Lorentz theory, the same results can be obtained [80]. Moreover, due to the sub-wavelength nature of the localized graphene plasmons, the final formulas can be simplified using the polynomial approximation of the special functions [81]. These structures can also be used as the building blocks of optical meta-materials [82].

Purcell factor and energy transfer between donor-acceptor emitters
As mentioned earlier, one of the important applications of Green's function is studying the interaction of dipole emitters in the vicinity of nanostructures. For this purpose, a vertical dipole in the vicinity of the graphene-based spherical structure, which was introduced in the previous section, is considered and its Purcell factor is calculated using the Green's function. Assuming that the field point and observation points for the dipole with moment d ⊥ 0 ¼ d 0r are in the same location of r 0 ¼ Δ > R 1 , θ 0 ¼ 0, and ϕ 0 ¼ 0, by calculating the scattered field using the convolution integral and the use of [18]: where symbol I m represents the imaginary part of the complex function. The decay rate can be calculated. For this purpose, using relationships: The scattered field can be calculated. Thus [73]: As can be seen, the above equation is in full agreement with [83] which has extracted the decay rate for a core-shell plasmonic sphere, whereas in this case, it is necessary to use the Mie coefficients of graphene-based structure, namely, B 11 V . Using the derived formulas, the positions of the dipole can be considered arbitrarily. The transferred energy between the donor-acceptor pairs can be calculated straightforwardly using the Green's function G as [84]: where the subscript 0 refers to the free-space parameters and d A and d B are respectively the dipole moments of the acceptor and donor.

Conclusion
In conclusion, dyadic Green's function extraction for planarly, cylindrically, and spherically layered medium based on scattering superposition method is a unified approach to deal with a wide range of electromagnetic problems in the realm of biomedicine. Specifically, the interaction of the human skin, body, and head with the electromagnetic sources with arbitrary distributions can be studied. Moreover, by engineering the constitutive parameters of the layers, a variety of novel devices for medical diagnostics and treatment can be proposed. Plasmonic metals and 2D materials are two main categories of such materials. For the sake of efficient analytical analysis, the impedance boundary condition is satisfied in the case of 2D materials to be used in the design of compact devices. of generalized printed transmission lines," IEEE transactions on Microwave Theory and Techniques, vol. 28, no. 7, pp. 733-736, 1980.