Abstract
This paper is devoted to the study of the transmission properties of Slanted Annular Aperture Arrays made in perfectly conducting metal. More precisely, we consider the transmission based on the excitation of the cutoff-less guided mode, namely the TEM mode. We numerically and analytically demonstrate some intrinsic properties of the structure showing a transmission coefficient of at least 50% of an unpolarized incident beam independently of the illumination configuration (angle and plane of incidence). The central symmetry exhibited by the structure is analytically exploited to demonstrate the existence of a polarization state for which all the incident energy is transmitted through the sub-wavelength apertures when the eigenmode is excited, whatever are the illumination and the geometrical parameters. For this state of polarization, the laminar flow of the energy through the structure can exhibit giant deviation over very small distances. An example of energy flow deviation of 220° per wavelength is presented for illustration. The results presented in this paper could be considered as an important contribution to the understanding of the enhanced transmission phenomenon based on the excitation of guided modes.
© 2015 Optical Society of America
1. Introduction
The enhanced light transmission (ET) phenomenon through sub-wavelength apertures in metal plates have already attracted researchers’ attention [1, 2]. This is mainly due to the observation made by T. W. Ebbesen’s team of an extraordinary optical transmission (EOT) which inevitably revolutionized the field of nano-optics and opened a wide range of applications from spectral filtering to nano-antennas via single molecule spectroscopy [3]. Plasmonics has taken full advantage of this boom because the high transmission was associated with the excitation of a surface plasmon resonance of the metallic layer that supports the engraved sub-wavelength apertures [4, 5]. Nonetheless, enhanced transmission could be obtained through a simple phenomenon of light guiding in even smaller apertures without the need of plasmons [6–8]. In fact, some metallic waveguide geometries (section shape) allow the existence of a guided mode with a relatively large cutoff wavelength compared to the waveguide transverse dimensions. This is specially the case of waveguides having a multi-connected conductor contours such as the coaxial waveguide (bi-connected) [9–11]. Indeed, the fundamental mode of such waveguide is a Transverse ElectroMagnetic (TEM) mode that has no cutoff [12]. Enhanced transmission through annular aperture arrays (AAA) due to the excitation of this peculiar mode was already theoretically studied [13–15] and recently experimentally demonstrated [16]. However, very difficult experimental constraints (especially the implementation of a large angle of incidence) must be met in order to obtain efficient excitation of the TEM mode [17]. More than ten years ago, efficient enhanced transmission (up to 93% in the visible range) through these AAAs was obtained using the excitation of the second guided mode [18,19], the TE11 mode that exhibits a large wavelength cutoff compared to the waveguide diameter. The properties of the EOT based on the excitation of this mode were studied by several groups. For example, it was clearly demonstrated that the resulting ET is angle and polarization independent [20] since the diffraction anomalies (Wood and Rayleigh) are spectrally far from the transmission peak position. In addition, due to the small metal thickness, the TE11 mode is mainly excited at its cutoff, meaning that it is associated to a very low group velocity and a quasi-infinite phase velocity [21]. All these attributes provide quite interesting properties for applications in various fields as the protection of radars (radomes) [22], photovoltaic, non-linear enhancement [23], optical trapping [24] or also in the design of metamaterials with giant artificial birefringence [25].
2. The SAAA structure
Recently, in order to bypass the experimental constraints associated with the excitation of the TEM mode, a slanted annular aperture array (SAAA) structure (see Fig. 1) was proposed, fabricated and characterized [16]. Indeed, the TEM mode is then excited at normal incidence and its spectral position is red-shifted compared to the conventional AAA structure. In fact, due to the inclined path through the metal film, the effective thickness of the cavities is larger and the phase matching condition can be fulfilled for larger values of the wavelength. Unfortunately, the TEM-based transmission in the visible range was weak due to metal losses and to the fact that this TEM-like mode is spatially extended in the metal more than the TE11 mode. Thus, in this paper, we will address theoretical and numerical simulations (through homemade 3D-Finite Difference Time Domain algorithm) only in case of microwave and THz domain where metals can be considered as perfectly electric conductors leading to efficient transmission as shown in Fig. 2. In this figure, a comparison between the transmission of an AAA and a SAAA structures (see Fig. 2(a)) having the same film thickness (h) is presented. The AAA structure is illuminated at oblique incidence with an angle of incidence equals to the tilt angle (θ = α) of the SAAA structure while this later is illuminated at normal incidence. The incident polarization is TM (magnetic field perpendicular to the plane of incidence); As shown in Fig. 2(b) the TEM-based transmission peak appears and reaches 100% for both structures. Nevertheless, its spectral position is significantly redshifted when the apertures are tilted. Indeed, since the Rayleigh anomaly is far from the spectral position λTEM of the TEM-based transmission peak (structure period p < π (Ri + Ro)), λTEM can be given by a phase matching relation:
where m is a non-zero positive integer, neff is the real part of the effective index of the TEM mode (neff = 1 if perfect conductor) and ϕr is a phase change due to the mode reflection (and diffraction) at the input or the output side. α is the angle of the aperture tilt counted from the normal to the metal interface. The position of the TEM peak can then be tuned through the tilt angle for a fixed value of the thickness. Nevertheless, this dependence is not completely explicit because the phase term (ϕr) can also depend on α. In order to gain more insight, we have studied the transmission response as a function of α at a fixed value of the thickness h = 2p/3 and in the case of normal incidence. In both cases, the radii of the annular aperture are fixed to Ro = p/3 and Ri = p/6. The results are plotted in Fig. 3(a) for α varying from 5° to 45°. As expected from Eq. (1), the TEM peak position shifts to the red region of the spectrum when α increases (1/cosα increases). Figure 3(b) depicts the spectral positions of the TEM peak as a function of 1/cosα (solid blue curve). An almost linear behavior is obtained meaning that the phase ϕr is quite constant when α varies. The slight discrepancy appearing at small values of α between the numerical calculation and that obtained from Eq. (1) when considering ϕr = 1.9 rad (dashed red line) is attributed to the coupling between the TEM and the TE11 modes. Thus, the light is totally transmitted through the structure independently of the value of α but at different wavelengths.On the other hand, Eq. (1) does not show any explicit relation between λTEM and the angle of incidence θ. Nonetheless, one can intuitively suspect a relation between this angle and the phase term ϕr. Numerical simulations presented in Fig. 4(a), corresponding to a tilt angle α = 35° and an angle of incidence that varies from −45° to 45°, show that the spectral position and the maximum value (100%) of the TEM-based transmission peak is independent of the angle of incidence. Only the quality factor (peak sharpness) is affected and it is maximum at normal incidence. In addition, for the sub-wavelength regime, there is a perfect symmetry of the transmission variations with respect to the normal incidence (T(−θ) = T(θ)), as shown in Fig. 4(b), where two spectra corresponding to θ = ±40° are plotted. This property is a consequence of the energy balance and the reciprocity theorem as analytically demonstrated in the appendix (see paragraphs 1 and 3) from the study of the transmission scattering matrix [26, 27]. The symmetry of the spectra with respect to the angle of incidence can be understood intuitively by the fact that the apertures are sub-wavelength details of the structure, and therefore cannot be detected in the far-field. On the contrary, for λ < λRayleigh the transmission spectra do not exhibit any symmetry. In this spectral range, propagating diffracted orders exist and their efficiencies depend on the tilt angle. Consequently, the diffracted zero order transmission changes with respect to the energy carried by these homogeneous orders. The obtained symmetry breaking, due to energy loss in the propagated diffraction orders, is clearly illustrated in Fig. 4(b) where the diffracted zero order is more efficient when the angle between the incident light and the aperture axis (tilt direction) is small (blue curve of Fig. 4(b)) compared to the opposite incident angle case (red curve of Fig. 4(b)). Let us notice that the property of symmetry with respect to the angle of incidence is valid for any resonance of the transmission as illustrated in the same Fig. 4(a) where the two TE11-based transmission peaks exhibit the same symmetry properties with respect to the normal incident axis (θ = 0°) and also reach 100% independently of the angle of incidence. Nevertheless, for large values of θ (20°), the Rayleigh anomaly approaches the TE11-based transmission peaks and a coupling between the two resonances occur resulting in a modification of the transmission properties.
3. Transmission properties
As already mentioned, an important information from these spectra is that, for the SAAA structure, which exhibits a central symmetry (see Appendix), the transmission reaches 100% at the wavelength resonance whatever the angle of incidence for a fixed value of the tilt angle. This property is replaced with another surprising property when one considers planes of incidence that are not along a direction of periodicity of the structure, as shown in Fig. 5, where different illumination configurations are considered by varying both the angle of incidence θ and the azimuthal one ϕ assuming β = 0°. For each couple (θ, ϕ), the two polarization states (TE, TM) are studied and we found that the sum of the transmission at the TEM-based peak is equal to 100% whatever the couple (θ, ϕ) is. In Figs. 5(a,b) and 5(e,f), we also observe the discontinuities corresponding to Rayleigh anomalies indicated by the indexes ((0,−1) and (−1,0)). The fact that for the structure under study, the sum of the transmittivities for TE and TM incident polarizations is equal to 100% at resonance whatever the angle of incidence, can be explained by analyzing the eigenvectors and eigenvalues of the matrix, where T1 is the scattering matrix of the structure and is the conjugate transpose of T1. The details are presented in the Appendix, which extends the demonstrations made in [26] and [27]. To sum-up, the two eigenvalues of the matrix are real and positive and they are the limits of the range of variation of the transmittivity when the polarization of the incident plane wave takes all possible states, even non linear polarization states (see the Appendix, first paragraph). The only necessary assumption is that the only propagative diffraction order is the zero order. The two eigenvectors, which are orthogonal to each other, correspond to the polarizations of the incident wave that allow to obtain these limits of transmittivity. Hence, it appears that it is better to work with the eigenvalues and eigenvectors of the matrix rather than with the transmittivities for TE and TM incident polarizations, especially for structures leading to polarization conversion.
Furthermore, if the structure has a symmetry center (see Fig. 6), it is possible to show (see the Appendix, paragraph 2–4) that one eigenvalue of the matrix reaches 100% when one eigenmode is excited, provided that the materials are lossless. Note that if the structure is symmetrical with respect to an axis normal to the plane containing the directions of periodicity of the structure, the same property occurs for the reflectivity, while if the structure is symmetrical with respect to a plane containing the directions of periodicity, both reflectivity and transmittivity reaches 100% for neighbouring wavelengths around resonance, as shown in [26] and [27].
Coming back to the SAAA structure presenting a center of symmetry, we can say that there exists a polarization state (Pmax) for which the transmission reaches 100%. Moreover, in our case, as we consider small apertures in a metallic plate, the orthogonal Pmin polarization state leads to a negligible transmission, or eventually to a residual transmission due, for example, to the presence of another resonance at a different wavelength. The Pmax polarization is clearly the TM polarization when β = ϕ = 0 (see Fig. 7), meaning a plane of incidence parallel to the aperture axis. In the general case of arbitrary incident polarization, because of the fact that the Pmax and Pmin polarization are orthogonal to each other, the sum of the transmittivities for TE and TM polarizations is equal to the sum of the eigenvalues of the matrix, hence is close to 100%. This property is numerically verified through the results presented in Fig. 5 where different illumination configurations are considered by varying both the angle of incidence θ and the azimuthal one ϕ assuming β = 0°. For each couple (θ, ϕ), the two polarization states (TE, TM) are studied and we found that the sum of the transmission at the TEM-based peak is equal to 100% whatever the couple (θ, ϕ) is.
Let us now consider an arbitrary configuration where ϕ and β are simultaneously nonzero and different from each other. Consequently, we have fixed the geometrical and illumination parameters to : Ri = p/6, Ro = p/3, h = 2p/3, α = 30°, ϕ = 65°, β = 25° and θ = −35°. Figure 7(a) presents the numerical transmission spectra where the dashed red line and the solid blue one correspond to the TE and TM polarization states respectively. Once again, the sum of the transmission at λTEM is equal to 1. The two eigenvalues of the matrix are plotted in Fig. 7(b) where the solid green line corresponds to the polarization state Pmax while the dashed magenta one represents the Pmin state. As expected, perfect transmission is obtained at λTEM for the Pmax polarization while an almost zero transmission (2.6% only) occurs for the orthogonal polarization Pmin. Note that, for the Pmax polarization, other transmission maxima (up to 100%) arise corresponding to additional transmission resonances (especially due to the excitation of the TE11 guided mode at two different wavelength values corresponding to Fabry-Perot harmonics). It is important to note that the eigenvectors corresponding to the eigenvalues plotted in Fig. 7(b) generally vary with the wavelength, hence, the polarization state allowing a 100% transmittivity may not be the same when the TEM and the TE11 modes are excited. From this study, it appears that when one eigenmode is excited, the transmission efficiency of an unpolarized incident beam at the resonance wavelength is, at least, equal to 50%. This is confirmed by the plot of the transmittivity for an unpolarized wave in Fig. 7 Another conclusion is that a necessary condition to obtain a polarization independent transmittivity at resonance is to excite two eigenmodes.
4. Giant energy deviation
Finally, let us emphasize that in the sub-wavelength regime, at λTEM and for the polarization state Pmax, the incident energy is totally routed through the apertures for every value of the tilt angle. As an example, we consider a SAAA structure with α = 35° illuminated by a plane wave propagating at θ = ±75°. The calculated transmission spectra for the Pmax polarization state are presented in Fig. 8(a). A TEM-based transmission peak occurs at λTEM = 2.3p whatever the sign of θ. In order to visualize the energy propagation in the vicinity of the SAAA, the energy flow (Poynting vector) is also calculated and presented in a vertical plane containing the axis of the apertures. One can clearly see in Figs. 8(b) and 8(c) the giant bending of light that occurs over a distance as small as λ/5 (see the direction change of the white arrows at the bottom of the structure). In the vicinity of the structure, the light energy follows a serpentine path with laminar flow (total transmission) through the nano-structured metallic film after suffering a total deviation of 220° over a distance smaller than the wavelength.
5. Conclusion
In summary, we have studied the fundamental aspect of the enhanced transmission mechanism through the SAAA structure on the basis of both numerical and analytical calculations. As an additional result, we presented some properties of this structure that demonstrate a high potential for applications in various fields such as spectral filtering regardless of the illumination direction. The next step should address the potential enhancement of the transmission of unpolarized beams (more than 50%) by spectrally approaching two different resonances (here the TEM and the TE11 ones) without causing destructive coupling through a degeneracy breaking. This may require an acurate optimization of the parameters of the structure or more complex structures, as it was done in the case of all dielectric sub-wavelength periodic structures presenting a resonance peak due to the excitation of a leaky guided mode (guided mode resonance grating) [28, 29]. Nevertheless, the case of larger transmission of about 70% can be found in Fig. 7(b) and corresponds to a transmission based on the excitation of the TE11 mode (see peak δ in Fig. 7). The discussion of this result is very simple but it is out of the paper scope. The giant deviation of the energy flux over small distance presented in Figs. 8(c) and (d), brings a supplementary and comprehensive physical insight about the guided mode-based enhanced transmission paradigm without the need to resort to surface plasmons or other surface waves.
Appendix
We consider a periodic structure composed of lossless materials which presents only one propagating diffraction order (the zero order). From the study of the scattering matrix of the structure, we will derive some properties of its transmittivity. This appendix is an extension of the works published in [27] and [26], and similar properties could be derived for the reflectivity.
In the following, we will first show that the eigenvalues of the transmittivity matrix for the energy, denoted hereafter, are the limits of the variation of the transmittivity when the incident polarization takes all possible states, and that they are obtained for orthogonal polarizations (given by the eigenvectors). Thus, these eigenvalues are the key variables to understand the behavior of a sub-wavelength grating with respect to the incident polarization. This is true especially in the case where the eigenvectors are not simply the s and p vectors, which occurs in conical incidence or when particular eigenmodes are excited.
Second, using only the reciprocity theorem and the energy balance, and with no hypothesis on the symmetry of the structure, we will show that the eigenvalues of are unchanged when the angle of incidence is changed in its opposite, hence generalizing a property that is well know for gratings illuminated in classical incidence (plane of incidence perpendicular to the grating grooves). This is a new result that was not published in [26].
Third, we consider structures having a central symmetry (examples are shown in Figs. 1 and 6). This kind of symmetry was discussed in [27] which focused on gratings illuminated under classical incidence (plane of incidence containing a direction of periodicity) for which there is no polarization conversion, but it was not discussed in [26]. We show that when one mode is excited, one eigenvalue of reaches 100% at resonance. This means that the transmittivity is equal to 100% at the resonance wavelength when the incident polarization corresponds to that of the eigenvector associated with this eigenvalue, while the transmittivity is equal to the transmittivity of the structure out of resonance for the orthogonal polarization.
.1. From the scattering matrix to the transmittivity
We start from the scattering matrix S(κ, λ) relating the incoming field (from the substrate and the superstrate), with wavelength λ and wave-vector with in-plane component κ (lying in the xy-plane in Fig. 6), to the field diffracted by the structure in the zero order of diffraction. The reader can refer to [26] (sections 2 and 3) for a full definition of the scattering matrix and of the s and p vectors associated to each incident and diffracted field (in the superstrate and the substrate). This 4×4 matrix is composed with 4 blocks:
The reflection and transmission matrices Rj and Tj, where the subscript j = 1 (resp. j = 2) is used when the incident field comes from the superstrate (resp. substrate), are 2×2 matrix. They contain the reflection and transmission conversion coefficients of a s or p polarized field to a s or p polarized field. For example, T1 writes as
From the definition of the scattering matrix it follows that the energy τ transmitted in the substrate when the incident field comes from the superstrate only can be written as:
where and , are the eigenvalues and and the eigenvectors of the matrix , and I1 is a two-elements vector containing the s and p components of the amplitude of the incident field vector.It is important to note that is a hermitian matrix, thus its eigenvectors are orthogonal (in the sense of hermitian scalar product) to each other and its eigenvalues are real and positive. Hence, from Eq. (4), it follows that and are the limits of the variation of the transmittivity when the incident field takes all possible states of polarization (even non linear). These limits are obtained for two orthogonal polarizations. Moreover, for any two incident orthogonal polarizations, the sum of the transmittivity is equal to the sum of the eigenvalues.
.2. Properties of the scattering matrix
Several properties of the scattering matrix can be deduced from the energy balance and the reciprocity theorem. Again, the demonstration is given in [26] (section 3 and 5), and only the results will be reported here. Note that in the following, we will need to consider the scattering matrix for complex wavelengths. Hence, we use an expression of the energy balance suitable for a complex variable λ with complex conjugate λ̄:
where 1 stands for the unit diagonal matrix of size 2×2.The reciprocity theorem entails that S(−κ, λ) = t(S(κ, λ)) (where t(S) is the transpose of S) which can be written as:
Now, we shall demonstrate a property related to the symmetry of the structure with respect to a symmetry center C. We consider two configurations, as depicted in Fig. 6. In the first configuration Fig. 6(a) I1(κ, λ) and I2(κ, λ) are two elements vectors containing the amplitudes, in s and p polarizations, of the incident field coming from the superstrate and the substrate respectively, and D1(κ, λ), D2(κ, λ) stand for the diffracted field. In the second configuration Fig. 6(b), the structure is illuminated with I′1(−κ, λ) and I′2(−κ, λ) in such a way that I′2(−κ, λ) is the symmetric of I1(κ, λ) with respect to the center of symmetry C, and I′1(−κ, λ)) is the symmetric of I2(κ, λ):
Because the structure is symmetric with respect to C, the two configurations are physically equivalent, and we can say that the same equality is verified for the diffracted field:
From the definition of the scattering matrix, we write:
and, on the other hand:From Eqs. (14) and (15) using Eqs. (12) and (13), we deduce that
Finally, using the reciprocity theorem Eqs. (9)–(11), it follows that
.3. Properties of the eigenvalues
Let us now consider the energy transfer transmission and reflection matrices Tj*Tj and Rj*Rj, with j = 1 or 2. We shall demonstrate that their egienvalues are unchanged when the polar angle is changed in its opposite. The two eigenvalues for each of the matrices are denoted as and (with k = a or b), and and stand for the associated eigenvectors.
The first property comes from the energy balance. Multiplying Eq. (5) (resp. Eq. (6)), with (resp. ), it is easy to show that
The second property comes from the reciprocity theorem. Considering a given real κ, and from the definition of the eigenvalue of T1*(κ, λ)T1(κ, λ), we have . Using the relation between T1(κ, λ) and T2(−κ, λ) coming from the reciprocity theorem (Eq. (9)), we obtain
Taking the complex conjugate and multiplying the two sides of Eq. (19) with T2*(−κ, λ), we obtain that
This means that A similar demonstration using the definition of the eigenvalues of Rj*(κ, λ)Rj(κ, λ) (for j = 1 or 2) and the Eqs. (10) and (11) leads to for k = a and b (the two eigenvalues), and j = 1 or 2 (the two reflectivity matrices).Finally, applying both the energy balance and the reciprocity theorem, we obtain the following relation for the eigenvalues (k = a or b):
In other words, the energy balance and the reciprocity theorem entail that the two reflectivity (resp. transmittivity) matrices for the energy have the same eigenvalues, and that these eigenvalues are symmetrical with respect to the polar angle of incidence. This last property is the vectorial analog of the property which is well known for 1D blazed gratings illuminated in classical incidence (plane of incidence perpendicular to the grating grooves). Note that the eigenvectors of the reflectivity (resp. transmittivity) matrices for the energy do change when the polar angle is changed in its opposite, which means that in case of polarization conversion, the reflected and transmitted energy are not symmetric with respect to the polar angle of incidence for any state of polarization.
.4. Resonant behavior of the eigenvalues
In this paragraph, we shall demonstrate that one eigenvalue of the energy transmittivity matrix T1*T1 reaches 100% if the structure has a central symmetry. From now, we consider a configuration for a given real κ where only one eigenmode of the structure can be excited. This means that the equation det(S−1(κ, λ)) = 0 has one complex solution λ = λp(κ) where λp(κ) stands for the dispersion relation of the eigenmode. We introduce the eigenvalues and and eigenvectors and of the matrix R1. We suppose that only one of the two eigenvalues of R1 shows a resonant behavior, the other remaining a slowly varying function. We have checked numerically the validity of this hypothesis for the configuration under study. Following the arguments given in [26] (end of section 4), for λ in the vicinity of λp(κ) we write the resonant eigenvalue, say , as
where u(κ, λ) is a function with neither roots nor poles, and a complex number. The unicity of the root of , which is due to the fact that only one mode is excited, is an important property that will be used at the end of the proof.When , we obtain that . Introducing this in Eq. (5), where the two sides have been multiplied with , we obtain
which is nothing but the eigenvector equation for T1*T1. This means that for , one eigenvalue of T1*T1, say is equal to unity. Its eigenvector is . In other words, and not surprisingly, for , the maximum of transmittivity is obtained when the incident configuration leads to a zero reflected field.We shall now prove that the symmetry of the structure with respect to a symmetry center entails the fact that is real, meaning that the transmittivity can reach 100% for a real wavelength value. Multiplying the two sides of Eq. (8) with and taking leads to
Using Eq. (17), we obtain As can not be null (otherwise from Eq. (26), would be null), we deduce that is the eigenvector of R1 associated with an eigenvalue which is null for . As has only one root and has no root, we conclude that is real. Hence, we have shown that there exists one real wavelength for which one eigenvalue of the matrix T1*T1 is equal to 100%.Acknowledgments
The thesis of T. Alaridhee is funded by Iraqi government through the ministry of “Higher Education & Scientific Research”. This work is partially supported by the French Center for Scientific Research (CNRS) contract ”ESENCYAL” under the number ANR-13-ASTR-0019-01, by the Labex ACTION and by the Franche-Comté Unviersity computing center: “Mesocentre de calcul de Franche-Comté”.
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