Introduction
Sakli et al. [Reference Sakli, Yahia, Fathallah, Tao and Aguili1] investigated the propagation characteristics of wave modes in a metallic circular waveguide filled with anisotropic metamaterial. In this way, by assuming the existence of TEz and TMz waves related to the waveguide axis in the mentioned system, they obtained and analyzed the wave equation and dispersion relations for TEz and TMz modes in the waveguide.
Now it is worth asking the question whether circular metal waveguides filled with anisotropic metamaterial can support an electromagnetic wave with TEz (or TMz) mode or not. The purpose of this work is to investigate this issue. We should point out that in the general case, hybrid wave propagation should be expected for such systems [Reference Moradi2–Reference Moradi and Bait-Suwailam4], and therefore TEz and TMz waves are unable to propagate. This means that in the general case, the results derived by Sakli et al. [Reference Sakli, Yahia, Fathallah, Tao and Aguili1] are incorrect.
The rigorous electromagnetic analysis
Let us consider a z-directional metallic circular waveguide filled with a metamaterial possesses anisotropic material parameters that are described by tensors diagonalized in a cylindrical coordinate system. Taking the coordinate axis to coincide with the waveguide axis, these take the form 
$\bar{\bar\varepsilon}=\bar{\bar I}\left( \varepsilon_{rr},\varepsilon_{r \theta},\varepsilon_{rz}\right) \varepsilon_{0}$ and 
$\bar{\bar\mu}=\bar{\bar I}\left( \mu_{rr},\mu_{r \theta},\mu_{rz}\right) \mu_{0}$ in which 
$\bar{\bar I}$ is the identity dyadic [Reference Sakli, Yahia, Fathallah, Tao and Aguili1]. In fact 
$\bar{\bar\varepsilon}$ and 
$\bar{\bar\mu}$ tensors have zero off-diagonal elements (biaxial material). Substituting electric and magnetic fields E and H describing a wave traveling in the z-direction
\begin{equation}
\qquad\qquad\qquad\qquad\qquad\textbf{E}(r,\theta,z)=\left[\textbf{e}_{r}E_{r}(r,\theta)+\textbf{e}_{\theta}E_{\theta}(r,\theta)+\textbf{e}_{z}E_{z}(r,\theta) \right]e^{-jk_{z} z}\;, \end{equation}
\begin{equation} \qquad\qquad\qquad\qquad\qquad\quad
\textbf{H}(r,\theta,z)=\left[\textbf{e}_{r}H_{r}(r,\theta)+\textbf{e}_{\theta}H_{\theta}(r,\theta)+\textbf{e}_{z}H_{z}(r,\theta) \right]e^{-jk_{z} z}\;, \end{equation} into Maxwell curl equations, i.e., 
$\nabla\times\textbf{E}=-j\omega\bar{\bar\mu}\cdot\textbf{H}$ and 
$\nabla\times\textbf{H}=j\omega\bar{\bar\varepsilon}\cdot\textbf{E}$, we can determine Er, Eθ, Hr, and Hθ with respect to partial derivatives of components Ez and Hz, as shown by Eqs. (5)–(8) in [Reference Sakli, Yahia, Fathallah, Tao and Aguili1]. By substituting Er, Eθ, Hr, and Hθ into z-components of Eqs. (1) and (2) in [Reference Sakli, Yahia, Fathallah, Tao and Aguili1], one may obtain the following coupled equations for components Ez and Hz as
\begin{align}
&\qquad\qquad\qquad\qquad\qquad\quad\dfrac{\partial^{2}H_{z}}{\partial r^{2}}+\dfrac{1}{r}\dfrac{\partial H_{z}}{\partial r}+\left( \dfrac{K_{c.\theta}\sqrt{\mu_{r\theta}}}{K_{c.r}\sqrt{\mu_{rr}}}\right)^{2}\dfrac{1}{r^{2}}\dfrac{\partial^{2}H_{z}}{\partial\theta^{2}}\nonumber\\
&\qquad\qquad\qquad\qquad\qquad\quad\quad{}+\left(\dfrac{\sqrt{\mu_{rz}}}{\sqrt{\mu_{rr}}}K_{c.\theta} \right)^{2}H_{z} =\dfrac{k_{z}k_{0}^{2}}{r\omega\mu_{0}\mu_{rr}} \dfrac{\mu_{r\theta}\varepsilon_{rr}-\mu_{rr}\varepsilon_{r\theta}}{K_{c.r}^{2}}\dfrac{\partial^{2}E_{z}}{\partial r\partial\theta}\;,
\end{align}
\begin{align}
&\dfrac{\partial^{2}E_{z}}{\partial r^{2}}+\dfrac{1}{r}\dfrac{\partial E_{z}}{\partial r}+\left( \dfrac{K_{c.r}\sqrt{\varepsilon_{r\theta}}}{K_{c.\theta}\sqrt{\varepsilon_{rr}}}\right)^{2}\dfrac{1}{r^{2}}\dfrac{\partial^{2}E_{z}}{\partial\theta^{2}}\nonumber\\
&\quad{} +\left(\dfrac{\sqrt{\varepsilon_{rz}}}{\sqrt{\varepsilon_{rr}}}K_{c.r} \right)^{2}E_{z} =\dfrac{k_{z}k_{0}^{2}}{r\omega\varepsilon_{0}\varepsilon_{rr}} \dfrac{\mu_{r\theta}\varepsilon_{rr}-\mu_{rr}\varepsilon_{r\theta}}{K_{c.\theta}^{2}}\dfrac{\partial^{2}H_{z}}{\partial r\partial\theta}\;,
\end{align} where 
$K_{c.r}^{2}=k_{0}^{2}\varepsilon_{rr}\mu_{r\theta}-k_{z}^{2}$, 
$K_{c.\theta}^{2}=k_{0}^{2}\varepsilon_{r\theta}\mu_{rr}-k_{z}^{2}$, and 
$k_{0}^{2}=\omega^{2}\varepsilon_{0}\mu_{0}$, and all other parameters in the equations of the present work were defined in [Reference Sakli, Yahia, Fathallah, Tao and Aguili1].
The TEz and TMz modes are defined by assuming 
$E_{z}=0$ and 
$H_{z}=0$, respectively. Now, let us explore the possibility of TEz and TMz wave propagation in the system. If we assume 
$E_{z}=0$, then Eqs. (3) and (4) reduce to
\begin{align}
\dfrac{\partial^{2}H_{z}}{\partial r^{2}}+\dfrac{1}{r}\dfrac{\partial H_{z}}{\partial r}+\left( \dfrac{K_{c.\theta}\sqrt{\mu_{r\theta}}}{K_{c.r}\sqrt{\mu_{rr}}}\right)^{2}\dfrac{1}{r^{2}}\dfrac{\partial^{2}H_{z}}{\partial\theta^{2}}\nonumber\\
+\left(\dfrac{\sqrt{\mu_{rz}}}{\sqrt{\mu_{rr}}}K_{c.\theta} \right)^{2}H_{z} =0\;,
\end{align}
\begin{equation}
\dfrac{k_{z}k_{0}^{2}}{r\omega\varepsilon_{0}\varepsilon_{rr}} \dfrac{\mu_{r\theta}\varepsilon_{rr}-\mu_{rr}\varepsilon_{r\theta}}{K_{c.\theta}^{2}}\dfrac{\partial^{2}H_{z}}{\partial r\partial\theta}=0\;.
\end{equation}The TEz waves must satisfy Eqs. (5) and (6). In Sakli et al. work [Reference Sakli, Yahia, Fathallah, Tao and Aguili1], the authors obtained Eq. (5) for TEz waves (see Eq. (12) in [Reference Sakli, Yahia, Fathallah, Tao and Aguili1]) but Eq. (6) was neglected. This means that the calculations for TEz modes in Sakli et al. paper [Reference Sakli, Yahia, Fathallah, Tao and Aguili1] do not satisfy Eq. (6), and therefore there is an obvious and serious error in [Reference Sakli, Yahia, Fathallah, Tao and Aguili1]. In physics, the presence of such a significant error in the investigation of a problem is unacceptable and inevitably leads to incorrect results [Reference Moradi5].
Note that Eqs. (5) and (6) cannot be simultaneously satisfied by the same value of kz unless in two particular cases. In the first case, material parameters must satisfy the condition
\begin{equation}
\mu_{r\theta}\varepsilon_{rr}=\mu_{rr}\varepsilon_{r\theta}\;.
\end{equation}In the second case, decoupling occurs if
\begin{equation}
\dfrac{\partial H_{z}}{\partial r}=0,\;\;\;\; \mathrm{or} \;\;\;\;\dfrac{\partial H_{z}}{\partial \theta}=0 \;.
\end{equation}These conditions reduce Eq. (6) to zero. Hence, in general TEz modes cannot propagate in a metallic circular waveguide filled with anisotropic metamaterial. However, from Eq. (7) it is easy to conclude that TEz and TMz modes can propagate separately in a metallic circular waveguide when it is filled with uniaxial media, i.e.,
\begin{equation}
\varepsilon_{rr}=\varepsilon_{r\theta},\;\;\;\; \mathrm{and} \;\;\;\;\mu_{r\theta}=\mu_{rr}\;.
\end{equation} In other words, the analysis by Sakli et al. [Reference Sakli, Yahia, Fathallah, Tao and Aguili1] is valid for uniaxial cases. Similarly, if we assume that 
$H_{z}=0$ (TMz modes), then Eqs. (3) and (4) reduce to
\begin{align}
\dfrac{\partial^{2}E_{z}}{\partial r^{2}}+\dfrac{1}{r}\dfrac{\partial E_{z}}{\partial r}+\left( \dfrac{K_{c.r}\sqrt{\varepsilon_{r\theta}}}{K_{c.\theta}\sqrt{\varepsilon_{rr}}}\right)^{2}\dfrac{1}{r^{2}}\dfrac{\partial^{2}E_{z}}{\partial\theta^{2}}\nonumber\\
+\left(\dfrac{\sqrt{\varepsilon_{rz}}}{\sqrt{\varepsilon_{rr}}}K_{c.r} \right)^{2}E_{z} =0\;,
\end{align}
\begin{equation}
\dfrac{k_{z}k_{0}^{2}}{r\omega\mu_{0}\mu_{rr}} \dfrac{\mu_{r\theta}\varepsilon_{rr}-\mu_{rr}\varepsilon_{r\theta}}{K_{c.r}^{2}}\dfrac{\partial^{2}E_{z}}{\partial r\partial\theta}=0\;,
\end{equation} Again, Eqs. (10) and (11) cannot be simultaneously satisfied unless material parameters satisfy the condition 
$\mu_{r\theta}\varepsilon_{rr}=\mu_{rr}\varepsilon_{r\theta}$, or when we have either 
$\partial E_{z}/\partial r=0, $ or 
$\partial E_{z}/\partial \theta=0 $. Thus, one may conclude that in the general case, a metallic circular waveguide filled with anisotropic metamaterials cannot support the propagation of TMz modes. This means that the results for TMz modes, derived by Sakli et al. (see Eq. (18) in [Reference Sakli, Yahia, Fathallah, Tao and Aguili1]) are also incorrect.
Conclusion
In summary, we have demonstrated that, in general, a metallic circular waveguide filled with anisotropic metamaterial cannot support the propagation of TEz and TMz waves. Consequently, the results derived by Sakli et al. are incorrect. However, their calculations are valid for uniaxial cases (where 
$\varepsilon_{rr}=\varepsilon_{r\theta}$ and 
$\mu_{r\theta}=\mu_{rr}$). In fact, uniaxial media represent a specific case of the condition shown in Eq. (7).
Competing interests
The authors declare no conflicts of interest/competing interests.
Afshin Moradi was born in Kermanshah, Iran, in 1977. He received the B.S., M.S., and Ph.D. degrees in physics from Razi University, Kermanshah, Iran, in 2000, 2003, and 2009, respectively. Since 2010, he has been with the Department of Engineering Physics, Kermanshah University of Technology, Kermanshah, where he is currently a Full Professor.
His research interests include plasmonics, electromagnetism, metamaterials, oscillations, and waves in plasmas. He has authored or coauthored more than 100 refereed journals papers on these topics, and a reviewer for many prestigious journals. He is the author of Canonical Problems in the Theory of Plasmonics, Springer Series in Optical Sciences, (Springer, 2020) and Theory of Electrostatic Waves in Hyperbolic Metamaterials, Springer Series in Optical Sciences (Springer, 2023).
