Abstract
We present the theory of electromagnetic energy propagation through a dispersive and absorbing hyperbolic metamaterial (HMM). In this way, the permittivity tensor components of HMM (especially, nanowire HMM) may appear to be hopeless, but as a non-trivial step, we find that they can be cast into more transparent forms. We find under the influence of an electromagnetic wave, the responses of nanowire HMM (multilayer HMM) in the directions perpendicular to and parallel to the optical axis are similar to those of Lorentz (Drude) and Drude (Lorentz) media, respectively. We obtain simple expressions for the electromagnetic energy density formula of both typical structures of HMMs, i.e., nanowire and multilayer HMMs. Numerical examples reveal the general characteristics of the direction-dependent energy storage capacity of both nanowire and multilayer HMMs. The results of this study may shed more physical insight into the optical characteristics of HMMs.
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Introduction
Metamaterials are artificial media that usually refer to arrays of wires and split-ring resonators (SRRs)1,2. They have unusual optical properties such as negative refractive index3, subwavelength imaging4, and indefinite permittivity5. A fundamental problem concerning dispersive and absorbing metamaterials is how to obtain electromagnetic energy density6,7,8,9,10,11. Actually, the contradictory results of electromagnetic energy density in lossy wire-SRR metamaterials have been the subject of theoretical controversy12,13,14,15.
If the losses are negligible, one can correctly obtain the electromagnetic energy density of such media by using the well-known Landau formula16. In the presence of damping effects, on the other hand, difficulties arise in attempting to calculate the energy associated with an electromagnetic wave passing through the wire-SRR metamaterials. During past years, several researchers achieved different results in different ways12,13,14,15. The question then becomes, what is the correct result for the electromagnetic energy density in dispersive and absorbing wire-SRR metamaterials? In this way, one of the present authors derived the electromagnetic energy density formula, which is consistent with the Landau formula, when the losses are negligible17. Then, Luan et al. obtained the electromagnetic energy density formula for the single-resonance chiral metamaterials18, using the same approach discussed in17.
An HMM refers to an extremely anisotropic uniaxial optical media and has received much attention recently19,20,21,22,23,24,25,28. This medium has opposite signs of the two principal values of the permittivity tensor along and perpendicular to its optical axis. Mathematically, the dispersion of an electromagnetic wave in such a medium has a hyperbolic shape. By definition, there are two types of HMMs. Type I with a predominantly dielectric nature, and type II with a predominant metallic behavior26. Typically, HMMs contain alternating deeply subwavelength metal and dielectric features and there are different configurations of HMMs such as metallic nanowire structures and dielectric-metal multilayer structures. Note that the signs of the two effective permittivities of such structures are frequency-dependent, so they are not definitely type-I HMM or type-II HMM and therefore an HMM is well-known as an indefinite medium27. However, a periodic array of metallic nanowires (for example gold nanowires) embedded in a host dielectric matrix (for example \(\hbox {SiO}_{2}\) ) may be an example of type-I HMM in the visible wavelength and near-IR range28. Also, a multilayer medium consisting of dielectric and metallic layers (for example gold-\(\hbox {SiO}_{{2}}\) HMM) may be an example of type-II HMM in the visible and near-IR range28. There are quite a number of interesting works on the characteristics and applications of HMMs, such as directional transmission29,30, long-range interaction31,32, and super-resolution imaging33,34. Also, the resonant modes of HMMs with oscillators have been studied in waveguide structures35 and cavity structures36,37. Interestingly, more recently, it has been shown that the propagation of sound waves in HMMs is similar to the gravitational waves, which means the quantized sound waves (phonons) are similar to gravitons38.
But what is the electromagnetic energy formula for a lossy HMM? Recently, one of the present authors studied the propagation of electromagnetic energy in a lossy multilayer HMM for a simple case39. However, the electromagnetic energy density formula in a lossy nanowire HMM has not been derived yet, perhaps because of its difficulty. In fact, the effective permittivities of HMMs are more complex than the wire-SRR and chiral metamaterials.
Solving the above-mentioned problem is the main motivation of the present work. However, to do this, the components of the well-known effective permittivity tensor of a nanowire HMM may appear to be hopeless, but they can be cast into more transparent forms. Actually, as a non-trivial and key step, we obtain familiar forms for the effective permittivities of nanowire HMMs and multilayer HMMs. Then, we can easily derive the energy density associated with an electromagnetic wave passing through them. Note that the new appropriate forms for the effective permittivities of nanowire HMMs and multilayer HMMs may shed more physical insight into the optical characteristics of HMMs. Finally, for the sake of completeness, we also find a new transparent form for the effective permittivity of a composite of metallic nano-spheres embedded in a host matrix (see the Supplementary Material).
Theory
Let us consider a dispersive and absorbing HMM as an effective uniaxial crystal. In the presence of an oscillating electric field \(\mathbf{E }=\mathbf{E }_{\parallel }+\mathbf{E }_{\bot }\) of frequency \(\omega\) and long-wavelength vibration, the equation of motion of this medium may be represented by the Lorentz equation. We have40
with \(\vartheta =\parallel ,\bot\). Also, q is the electric charge, m is the effective mass of each electric charge, \(\mathbf{r }=\mathbf{r }_{\parallel }+\mathbf{r }_{\bot }\) is the displacement of the oscillators, \(\omega _{\mathrm {0}\vartheta }\) is the resonance frequency of the charges and \(\gamma\) is the damping frequency. Note that the z-axis is along the optical axis of the HMM and \(E_{\parallel }=E_{z}\).
Suppose that there are N oscillators in the HMM with volume V and let us represent the effect of the high resonances by real constant background dielectric constants \(\varepsilon _{\infty \parallel }\) and \(\varepsilon _{\infty \bot }\). Then, we have
where \(\mathbf{P }_{\vartheta }\) is the \(\vartheta\) component of complex polarization that has a part due to the oscillators of natural frequency \(\omega _{\mathrm {0}\vartheta }\), and a part due to the higher frequency resonances. Therefore, the components of the relative permittivity tensor can be determined by using Eqs. (1) and (2) as \(\varepsilon _{\vartheta }=1+P_{\vartheta }/\varepsilon _{0}E_{\vartheta }\). The final outcome is
where \(F_{\vartheta }=\omega _{\mathrm {p}\vartheta }^{2}/\omega _{0\vartheta }^{2}\) measures the strength of the HMM resonance, \(\varepsilon _{x}=\varepsilon _{y}=\varepsilon _{\bot }\), \(\varepsilon _{z}=\varepsilon _{\parallel }\), and \(\omega _{\mathrm {p}\vartheta }=\left( Nq^{2}/\varepsilon _{0}\varepsilon _{\infty \vartheta }mV \right) ^{1/2}\).
Indeed, Eq. (3) suggests that the Lorentz formula is a general and suitable form for the components of the relative permittivity tensor of an HMM. The electromagnetic energy density for a Lorentz type of isotropic media [see Eq. (3)] has been derived earlier by Loudon40. Thus, the time-averaged total energy density associated with a harmonic wave in a Lorentz type of HMM is
where
is the electromagnetic energy density (\(\varepsilon _{0}\) and \(\mu _{0}\) are permittivity and permeability of free space, respectively, and \(\mathbf{H }\) is magnetic field), and
is the kinetic energy density of HMM, and
is the potential energy density of HMM. Therefore, in general, the total energy includes two parts: the first part from the electric and magnetic fields themselves, the second part from the medium response, i.e., the kinetic and potential energies of the charges under the influence of the electromagnetic wave41. Also, the time-averaged power loss density can be written as
Using Eq. (1) to eliminate \(\mathbf{r }_{\parallel }\) and \(\mathbf{r }_{\bot }\) from Eqs. (5)–(8), we obtain
where \(\Xi _{\parallel }\) and \(\Xi _{\bot }\) are the effective energy coefficients as
and
where \({\text {Im}}\) means imaginary part, and \(\Gamma _{\parallel }\) and \(\Gamma _{\bot }\) are the effective energy loss coefficients as
If the losses are negligible, the time-averaged electromagnetic energy density, for a monochromatic (single frequency) electromagnetic field, is16
Setting \(\gamma =0\) in Eq. (3) and using Eq. (13), we obtain
that is exactly the same result as that obtained by setting \(\gamma =0\) in Eq. (9). This equality is the first verification of the presented results.
Nanowire hyperbolic metamaterials
Now, let us consider a periodic array of metallic nanowires with axes parallel to z-axis embedded in a host dielectric matrix with the dielectric constant \(\varepsilon _{\mathrm {d}}\), as shown in Fig. 1a. The z-axis is along the optical axis. Let f be the filling fraction of the metallic nanowires in a unit cell satisfying \(0<f<1\). This periodic array can be used to construct an electric HMM of type I (in an appropriate frequency region), with the components of effective permittivity tensor given by21,42
where
shows the relative permittivity of a metallic nanowire with \(\varepsilon _{\infty }\) that is the permittivity in high-frequency and \(\omega _{\mathrm {p}0}\) as the electron plasma frequency. Here we have relaxed the restrictions in the previous investigation39 by considering \(\varepsilon _{\infty }\) in Eq. (17). Therefore the formulas might provide more realistic applications.
At this stage, as a non-trivial step, the above effective permittivities can be written as Eq. (3). The recipe for reducing Eqs. (15) and (16) to Eq. (3) is as follows
-
(1)
First, replace \(\varepsilon _{\mathrm {m}}\) with \(\varepsilon _{\infty }\).
-
(2)
Replace \(\varepsilon _{\vartheta }\) with \(\varepsilon _{\infty \vartheta }\) to find \(\varepsilon _{\infty \vartheta }\).
-
(3)
Find \(\omega _{\mathrm {p}\vartheta }^{2}=F_{\vartheta }\omega _{0\vartheta }^{2}\) from \(\varepsilon _{\vartheta }<0\), as \(\omega _{\mathrm {p}\vartheta }^{2}=f\varepsilon _{\infty }\omega _{\mathrm {p}0}^{2}/\varepsilon _{\vartheta }\) and consider \(\omega _{0\vartheta }=0\).
-
(4)
Consider \(\xi\) as the denominator of \(\varepsilon _{\vartheta }>0\), and find \(\omega _{0\vartheta }^{2}=(1-f)\varepsilon _{\infty }\omega _{\mathrm {p}0}^{2}/\xi\).
-
(5)
Consider \(\zeta\) as the product of the denominator and numerator of \(\varepsilon _{\vartheta }>0\), and find \(\omega _{\mathrm {p}\vartheta }^{2}=\eta ^{2}f\varepsilon _{\mathrm {d}}^{2}\varepsilon _{\infty }\omega _{\mathrm {p}0}^{2}/\zeta\). Note that \(\eta\) is a geometrical factor. \(\eta =1,2\) and 3 for slab, cylinder, and sphere inclusions, respectively.
-
(6)
Finally, for \(\varepsilon _{\vartheta }>0\) find \(F_{\vartheta }=\omega _{\mathrm {p}\vartheta }^{2}/\omega _{0\vartheta }^{2}\).
Using the mentioned step-by-step procedure, we obtain
These equations indicate that the optical responses of a nanowire HMM in directions perpendicular to the optical axis and parallel to it are similar to the Lorentz and Drude media, respectively, as shown in Fig. 1b. Using the above equations, we can obtain the energy relations of a nanowire HMM according to the Eqs. (9) and (11). For the case \(f\ll 1\), nanowires are well separated by large distances and there is no intermodal coupling between eigenmodes of them. Then from Eqs. (18)–(22) we find:
where \(\sqrt{\varepsilon _{\infty }}\omega _{\mathrm {p}0}/\sqrt{\varepsilon _{\infty }+\varepsilon _{\mathrm {d}}}\) is the frequency of dipolar resonance of a single metallic nanowire surrounded by a dielectric medium43. Note that for type-I HMM we should have \(\mathrm{Re}\left[ \varepsilon _{\mathrm {\parallel }}\right] <0\) and \(\mathrm{Re}\left[ \varepsilon _{\mathrm {\bot }}\right] >0\) (\({\text {Re}}\) means real part) and the imaginary parts of them must be small enough to be negligible. Therefore, using Eq. (3) we find \(\mathrm{Re}\left[ \varepsilon _{\mathrm {\parallel }}\right] <0\), if \(\omega <\sqrt{\omega _{\mathrm {p}\parallel }^{2}-\gamma ^{2}}\), and \(\mathrm{Re}\left[ \varepsilon _{\mathrm {\bot }}\right] >0\), if \(\omega <\omega _{0\bot }\), that means we may have \(\omega <\mathrm {min}\left( \sqrt{\omega _{\mathrm {p}\parallel }^{2}-\gamma ^{2}},\omega _{0\bot }\right)\). Although the results in this subsection were derived for a type-I nanowire HMM, however, the expressions are generally valid and can be used for a type-II nanowire HMM (in an appropriate frequency region). It is easy to find that for type-II nanowire HMM we may have \(\mathrm {max}\left( \sqrt{\omega _{\mathrm {p}\parallel }^{2}-\gamma ^{2}},\omega _{0\bot }\right)<\omega <\sqrt{1+F_{\bot}}\omega _{0\bot}.\)
Now, we study the corresponding dispersion/anisotropy and absorption effects in the energy density and power loss. Therefore, we use the directionality factors, as \({\mathcal {D}}_{\mathrm {energy}}=\Xi _{\bot }/\Xi _{\parallel }\), where \(\Xi _{\parallel }\) and \(\Xi _{\bot }\) are the effective energy coefficients in Eq. (9) as mentioned before, and \({\mathcal {D}}_{\mathrm {loss}}=\Gamma _{\bot }/\Gamma _{\parallel }\), where \(\Gamma _{\parallel }\) and \(\Gamma _{\bot }\) are the effective energy loss coefficients in Eq. (11). We assume \(\varepsilon _{\mathrm {d}}=\varepsilon _{\mathrm {SiO_{2}}=3.9}\), \(\varepsilon _{\infty }=1\), and \(\gamma =0.01\omega _{\mathrm {p}0}\).
Figure 3 shows the variation of \({\mathcal {D}}_{\mathrm {energy}}\) (blue curves), and \({\mathcal {D}}_{\mathrm {loss}}\) (red curves) as a function of the dimensionless frequency \(\omega /\omega _{\mathrm {p}0}\) for a nanowire HMM as type-I HHM (for example a gold nanowire HMM in the visible and near-IR range28) with different values of f. The energy storage ability and the absorption property of the system can be isotropic with respect to the electric field for specific cases. For example, from panel (c) one can see the absorption property becomes isotropic when \(f=0.2\) and \(\omega =\sqrt{\omega _{\mathrm {p}\parallel }^{2} -\gamma ^{2}}=0.245\omega _{\mathrm {p}0}\). Panels (c) and (d) show that the electric field should be applied to the direction normal to the optical axis to store more energy in the medium, when the frequency is in the vicinity of \(\sqrt{\omega _{\mathrm {p}\parallel }^{2}-\gamma ^{2}}\). Also, we see \({\mathcal {D}}_{\mathrm {loss}}\) and \({\mathcal {D}}_{\mathrm {energy}}\) decrease with decreasing the value of \(\omega /\omega _{\mathrm {p}0}\). It is easy to find that the energy storage ability of the system corresponding to low values of \(\omega\) is high, although the directionality factor indicates that the energy storage ability of the medium is anisotropic. Actually, for low values of \(\omega\), the electric field should be applied to the direction parallel to the optical axis to store more energy in the medium.
Multilayer hyperbolic metamaterials
Consider now a multilayer structure consisting of isotropic metal/dielectric layers, as shown in Fig. 2a. The z-axis is along the optical axis. Let \(\varepsilon _{\mathrm {m}}\) (\(\varepsilon _{\mathrm {d}}\)) be the relative permittivity of the metal (dielectric) layer, and let f be the filling ratio of the metal layer satisfying \(0<f<1\). Again, Eq. (17) shows the relative permittivity of a metallic layer. This multilayer structure can be used to construct an electric HMM of type II (in an appropriate frequency region) with the components of effective permittivity tensor given by21,44
We can rewrite Eqs. (25) and (26) as Eq. (3) [see the recipe for reducing Eqs. (15) and (16) to Eq. (3)]. In this case, we find
These equations show that the optical responses of a multilayer HMM in directions perpendicular to the optical axis and parallel to it are similar to the Drude and Lorentz media, respectively, as shown in Fig. 2b. Using the above equations, we can obtain energy relations of a multilayer HMM according to the Eqs. (9) and (11). Again, if we consider \(f\ll 1\) then from Eqs. (27)–(31) we find:
where \(\omega _{\mathrm {p}0}\) is the resonance frequency of a single metallic layer in a dielectric medium. This result indicates that the resonance effect also happens in the metallic layers. Note that this resonance frequency is free from the effect of permittivity of the dielectric medium.
Also, note that for type-II HMM we should have \(\mathrm{Re}\left[ \varepsilon _{\mathrm {\parallel }}\right] >0\) and \(\mathrm{Re}\left[ \varepsilon _{\mathrm {\bot }}\right] <0\). Therefore, using Eq. (3) we find \(\mathrm{Re}\left[ \varepsilon _{\parallel }\right] >0\), if \(\omega <\omega _{0\parallel }\), and \(\mathrm{Re}\left[ \varepsilon _{\bot }\right] <0\), if \(\omega <\sqrt{\omega _{\mathrm {p}\bot }^{2}-\gamma ^{2}}\), that means \(\omega <\mathrm {min}\left( \sqrt{\omega _{\mathrm {p}\bot }^{2}-\gamma ^{2}},\omega _{0\parallel }\right)\). Although the results in this subsection were derived for a type-II multilayer HMM, however, the expressions are generally valid and can be used for a type-I multilayer HMM (in an appropriate frequency region). It is easy to find that for type-I multilayer HMM we may have \(\mathrm {max}\left( \sqrt{\omega _{\mathrm {p}\bot }^{2}-\gamma ^{2}},\omega _{0\parallel }\right)<\omega <\sqrt{1+F _{\parallel }}\omega _{0\parallel }\).
Let us again study the corresponding dispersion/anisotropy and absorption effects in the energy density and power loss, when \(\varepsilon _{\mathrm {d}}=\varepsilon _{\mathrm {SiO_{2}}=3.9}\), \(\varepsilon _{\infty }=1\), and \(\gamma =0.01\omega _{\mathrm {p}0}\). Figure 4 shows the variation of \(1/{\mathcal {D}}_{\mathrm {energy}}\) (blue curves), and \(1/{\mathcal {D}}_{\mathrm {loss}}\) (red curves) as a function of the dimensionless frequency \(\omega /\omega _{\mathrm {p}0}\) for a multilayer HMM as type-II HHM (for example gold-SiO\(_{2}\) multilayer HMM in the visible and near-IR range28) with different values of f. As a specific case, one can see that the energy storage ability of the system becomes isotropic with respect to the electric field, when \(f\approx 0.223\) and \(\omega =\sqrt{\omega _{\mathrm {p}\bot }^{2}-\gamma ^{2}}=0.262\omega _{\mathrm {p}0}\). The power loss corresponding to these specific values is low, although the directionality factor indicates that the absorption property of the medium near \(\omega =0.262\omega _{\mathrm {p}0}\) is also anisotropic. Below this frequency, the system can store more energy if the electric field direction is parallel to the layers (normal to the optical axis).
Some applications
Energy velocity of TM wave in hyperbolic metamaterials
As an example of the application of the general energy density expression shown by Eq. (9), we now derive the formula for the energy velocity of a propagating transverse magnetic (TM) wave in an HMM. We note that the hyperbolic feature appears only for the TM polarized waves. For the sake of convenience, we consider a TM polarized wave with the field components \(E_{\bot }=E_{x}\), \(E_{\parallel }=E_{z}\), and \(H_{y}\) as
where the amplitude \(H_{0}\), has been defined to be real. Also, \(\mathbf{e }_{x}\), \(\mathbf{e }_{y}\) and \(\mathbf{e }_{z}\) are the unit vectors along the x, y and z axis, respectively, and \(k_{\bot }=k_{x}\), and \(k_{\parallel }=k_{z}\) denote the x, and z components of the wavevector. Note that
is the well-known dispersion relation of this TM wave25, where c is the speed of light in free space. The resulting dispersion relation is plotted in Fig. 5 for a nanowire HMM and a multilayer HMM as type-I and type-II HMMs in an appropriate frequency region. We assume that HMMs are nonabsorbing. In both cases, the contours of constant \(\omega\) are hyperbolas. In the type-I HMM, these hyperbolas are centered on the \(k_{\bot }\) axis, while in the type-II HMM, they are centered on the \(k_{\parallel }\) axis23,45.
The exact definition of the velocity, \(\mathbf{v }_{\mathrm {E}}\), with which energy is transported through the HMM is46
where \(\mathbf{S }\) is the time-averaged power flow and can be obtained from the Poynting vector by
in the complex number representation. This vector in the medium has components in the x- and z-directions, as
where, using Eq. (9) and Eqs. (39) and (40), we find the energy velocity components
If the losses are negligible, we obtain
where these results for \(\gamma =0\) can be deduced by taking the \(\mathbf{k }\)-gradient of the dispersion relation (36), i.e., \(\mathbf{v }_{\mathrm {G}}=\nabla _{\mathbf{k }}\omega\). Therefore, we find the equality between the group velocity and the energy velocity, when \(\gamma =0\). This equality is another verification of the presented results.
Wave damping property
As another example of the application of the energy density expression, we now study the frequency dependence of the damping function of a propagating TM wave in an HMM. To obtain an analytical expression for the damping function (which depends on the frequency and wavenumber) of a propagating TM wave in an HMM, we use the perturbative method proposed by Loudon40. Such a procedure enables us to calculate the true wave damping rate to the first order in the damping parameter \(\gamma\), introduced to describe the intrinsic damping of crystal oscillations. The advantage of perturbative method is that the damping properties result from the calculation of real dispersion relations. The plasmonic damping parameter or relaxation rate \(\Gamma (k_{\parallel },k_{\bot },\omega )\) of the present case may be determined by the following procedure. The kinetic and total energy densities (per unit area) \(U_{\mathrm {K}}\), and U are first calculated in the absence of damping. If a small amount of damping is now reintroduced, the wave relaxation rate to lowest order in \(\gamma\) is
where from Eq. (14) we have
Therefore, we get
Let us note that the frequency dependence of the damping function comes from the retarded part of the plasmonc waves and one can find that, in the nonretarded limit, the total energy density becomes twice as large as the kinetic energy density of the system. As a consequence, the damping function of plasmonic waves of the system equals \(\gamma\), i.e., it becomes a constant.
Wave relaxation time
Let us note that the wave relaxation time \(\mathcal {T}\), which determines the time rate of decay of power flow, is simply the inverse of Eq. (47), i.e.,
In fact, \(\mathcal {T}\) is the time at which the power flow at a point moving with the energy velocity is reduced to 1/e of its original value.
Wave propagation length
The wave propagation length \(\mathcal {L}\) is given by
where \(v_{\mathrm {E}}\) can be found from Eqs. (43) and (44) as \(v_{\mathrm {E}}=\left( v_{\mathrm {E}\parallel }^{2}+v_{\mathrm {E}\bot }^{2} \right) ^{1/2}\). In fact, the wave propagation length \(\mathcal {L}\) is the distance after which the power flow in the wave is reduced to 1/e of its original value. Let us note that the absorption coefficient for the wave \(\mathcal {A}\) is simply the inverse of Eq. (49), i.e.,
Conclusion
In summary, it seems that the structure of an HMM is much simpler than the wire-SRR and chiral metamaterials. But, the effective permittivities of HMMs are more complex than those of wire-SRR and chiral metamaterials. Therefore, the investigation of electromagnetic energy density in such media may be difficult. To remedy this hardship, as a non-trivial and key step, we have obtained familiar forms for the well-known effective permittivities of nanowire HMMs and multilayer HMMs, similar to the Lorentz and Drude media. These new transparent forms for the effective permittivities of the HMMs simply show that HMMs have different dynamical properties in the directions parallel and perpendicular to their optical axes. In this way, we have extended the previous results for the electromagnetic energy density in the single-resonance chiral18 and the wire-SRR11,17 metamaterials, and simply derived the energy density associated with an electromagnetic wave passing through an HMM. Note that we have checked the validity of the obtained results in two steps. First, we have shown the time-averaged energy density formula derived here, i.e., Eq. (9) is consistent with the well-known Landau formula, i.e., Eq. (13), when the losses are negligible. Second, we have shown the group velocity of the TM waves in a lossless HMM is the same as the energy velocity (i.e., the ratio of the power flow to the storage energy). Here we should stress that in the present work, we mainly study the electromagnetic energy density of TM waves in the electric HMMs. Similar results can be obtained in the propagation of transverse electric (TE) waves in the magnetic HMM47.
Data availability
The data that supports the findings of this study are available within the article.
References
Smith, D. R., Padilla, W. J., Vier, D. C., Nemat-Nasser, S. C. & Schultz, S. Composite medium with simultaneously negative permeability and permittivity. Phys. Rev. Lett. 84, 4184 (2000).
Sarychev, A. K. & Shalaev, V. M. Electrodynamics of Metamaterials (World Scientific, 2007).
Pendry, J. B. Negative refraction makes a perfect lens. Phys. Rev. Lett. 85, 3966 (2000).
Zhang, X. & Liu, Z. Superlenses to overcome the diffraction limit. Nat. Mater. 7, 435 (2008).
Smith, D. R., Kolinko, P. & Schurig, D. Negative refraction in indefinite media. J. Opt. Soc. Am. B 21, 1032 (2004).
Cui, T. J. & Kong, J. A. Time-domain electromagnetic energy in a frequency-dispersive left-handed medium. Phys. Rev. B 70, 205106 (2004).
Cao, H. & Cui, T. J. Electromagnetic energy in absorptive and dispersive medium based on the assembly of atomic oscillators. Microw. Opt. Technol. Lett. 48, 2288 (2006).
Webb, K. J. & Shivanand,. Electromagnetic field energy in dispersive materials. J. Opt. Soc. Am. B 27, 1215 (2010).
Luan, P. G. Lagrangian dynamics approach for the derivation of the energy densities of electromagnetic fields in some typical metamaterials with dispersion and loss. J. Phys. Commun. 2, 075016 (2018).
Chen, J., Xuanyuan, Y. & Dai, Y. Expressions of stored and dissipated energy densities. Optik 207, 163493 (2020).
Moradi, A. Distribution of electromagnetic energy density in a dispersive and dissipative metamaterial. J. Mod. Opt. 68, 634 (2021).
Ruppin, R. Electromagnetic energy density in a dispersive and absorptive material. Phys. Lett. A 299, 309 (2002).
Tretyakov, S. A. Electromagnetic field energy density in artificial microwave materials with strong dispersion and loss. Phys. Lett. A 343, 231 (2005).
Ikonen, P. M. T. & Tretyakov, S. A. Determination of generalized permeability function and field energy density in artificial magnetics using the equivalent-circuit method. IEEE Trans. Microw. Theory Tech. 55, 92 (2007).
Boardman, A. D. & Marinov, K. Electromagnetic energy in a dispersive metamaterial. Phys. Rev. B 73, 165110 (2006).
Landau, L. D. & Lifshitz, E. M. Electrodynamics of Continuous Media 2nd edn. (Pergamon Press, 1984).
Luan, P. G. Power loss and electromagnetic energy density in a dispersive metamaterial medium. Phys. Rev. E 80, 046601 (2009).
Luan, P. G., Wang, Y. T., Zhang, S. & Zhang, X. Electromagnetic energy density in a single-resonance chiral metamaterial. Opt. Lett. 36, 675 (2011).
Simovski, C. R., Belov, P. A., Atrashchenko, A. V. & Kivshar, Y. S. Wire metamaterials: Physics and applications. Adv. Mater. 24, 4229 (2012).
Poddubny, A., Iorsh, I., Belov, P. & Kivshar, Y. Hyperbolic metamaterials. Nat. Photon 7, 948 (2013).
Shekhar, P., Atkinson, J. & Jacob, Z. Hyperbolic metamaterials: Fundamentals and applications. Nano Convergence 1, 14 (2014).
Narimanov, E. & Kildishev, A. Naturally hyperbolic. Nat. Photon 9, 214 (2015).
Ferrari, L., Wu, C., Lepage, D., Zhang, X. & Liu, Z. Hyperbolic metamaterials and their applications. Prog. Quantum Electron 40, 1 (2015).
Smolyaninov, I. I. & Smolyaninova, V. N. Hyperbolic metamaterials: Novel physics and applications. Solid State Electron 136, 102 (2017).
Smolyaninov, I. I. Hyperbolic Metamaterials (Morgan and Claypool/Institute of Physics, 2018).
Montano, I. et al. Semiconductor hyperbolic metamaterials at the quantum limit. Sci. Rep. 8, 16694 (2018).
Smith, D. R. & Schurig, D. Electromagnetic wave propagation in media with indefinite permittivity and permeability tensors. Phys. Rev. Lett. 90, 077405 (2003).
Takayama, O. & Lavrinenko, A. V. Optics with hyperbolic materials [Invited]. J. Opt. Soc. Am. B 36, F38 (2019).
Kapitanova, P. V. et al. Photonic spin Hall effect in hyperbolic metamaterials for polarization-controlled routing of subwavelength modes. Nat. Commun. 5, 3226 (2014).
Guo, Z., Long, Y., Jiang, H., Ren, J. & Chen, H. Anomalous unidirectional excitation of high-k hyperbolic modes using all-electric metasources. Adv. Photon. 3, 036001 (2021).
Newman, W. D. et al. Observation of long-range dipole-dipole interactions in hyperbolic metamaterials. Sci. Adv. 4, eaar5278 (2018).
Guo, Z., Jiang, H., Li, Y., Chen, H. & Agarwal, G. S. Enhancement of electromagnetically induced transparency in metamaterials using long range coupling mediated by a hyperbolic material. Opt. Express 26, 627 (2018).
Lu, D. L. & Liu, Z. W. Hyperlenses and metalenses for far-field super-resolution imaging. Nat. Commun. 3, 1205 (2012).
Guo, Z. et al. Focusing and super-resolution with partial cloaking based on linear-crossing metamaterials. Phys. Rev. Appl. 10, 064048 (2018).
Guo, Z., Song, J., Jiang, H. & Chen, H. Miniaturized backward coupler realized by the circuit-based planar hyperbolic waveguide. Adv. Photon. Res. 2, 2100035 (2021).
Wang, Y. et al. Circuit-based magnetic hyperbolic cavities. Phys. Rev. Appl. 13, 044024 (2020).
Guo, Z., Jiang, H. & Chen, H. Zero-index and hyperbolic metacavities: Fundamentals and applications. J. Phys. D Appl. Phys. 55, 083001 (2022).
Smolyaninov, I. I. & Smolyaninova, V. N. Universe 8, 242 (2022).
Luan, P. G. Effective electrodynamics theory for the hyperbolic metamaterial consisting of metal-dielectric layers. Crystals 10, 863 (2020).
Loudon, R. Propagation of electromagnetic energy through an absorbing dielectric. J. Phys. A Gen. Phys. 3, 233 (1970).
Zheng, X. & Palffy-Muhoray, P. Electrical energy storage and dissipation in materials. Phys. Lett. A 379, 1853 (2015).
Moradi, A. Electrostatic theory of rectangular waveguides filled with anisotropic media. Sci. Rep. 11, 24522 (2021).
Moradi, A. Electrostatic wave propagation in an array of metallic wires. Phys. Plasmas 27, 064502 (2020).
Kim, K. H., No, Y. S., Chang, S., Choi, J.-H. & Park, H.-G. Invisible hyperbolic metamaterial nanotube at visible frequency. Sci. Rep. 5, 16027 (2015).
Wood, B., Pendry, J. B. & Tsai, D. P. Directed subwavelength imaging using a layered metal-dielectric system. Phys. Rev. B 74, 115116 (2006).
Moradi, A. Canonical Problems in the Theory of Plasmonics: From 3D to 2D Systems (Springer, 2020).
Guo, Z., Jiang, H. & Chen, H. Hyperbolic metamaterials: From dispersion manipulation to applications. J. Appl. Phys. 127, 071101 (2020).
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A.M. proposed the idea, performed the calculations, analyzed the numerical data, and wrote the manuscript. P.G.L. checked the results thoroughly and contributed to the review of the manuscript.
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Moradi, A., Luan, PG. Electromagnetic energy density in hyperbolic metamaterials. Sci Rep 12, 10760 (2022). https://doi.org/10.1038/s41598-022-14909-0
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DOI: https://doi.org/10.1038/s41598-022-14909-0
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