Terahertz polarization converter and one-way transmission based on double-layer magneto-plasmonics of magnetized InSb

Fei Fan; Shi-Tong Xu; Xiang-Hui Wang; Sheng-Jiang Chang

doi:10.1364/OE.24.026431

Terahertz polarization converter and one-way transmission based on double-layer magneto-plasmonics of magnetized InSb

Fei Fan, Shi-Tong Xu, Xiang-Hui Wang, and Sheng-Jiang Chang

Optics Express
Vol. 24,
Issue 23,
pp. 26431-26443
(2016)
•https://doi.org/10.1364/OE.24.026431

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Fei Fan, Shi-Tong Xu, Xiang-Hui Wang, and Sheng-Jiang Chang, "Terahertz polarization converter and one-way transmission based on double-layer magneto-plasmonics of magnetized InSb," Opt. Express 24, 26431-26443 (2016)

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Related Topics
Table of Contents Category
- Terahertz and X-ray Optics
Optics & Photonics Topics
?

The topics in this list come from the OSA Optics and Photonics Topics applied to this article.
Previously assigned OCIS codes
- Magneto-optical materials (160.3820)
- Plasmonics (250.5403)
- Spectroscopy, teraherz (300.6495)

About this Article
History
- Original Manuscript: September 27, 2016
- Revised Manuscript: November 2, 2016
- Manuscript Accepted: November 3, 2016
- Published: November 7, 2016

Accessible

Open Access

Abstract

In this work, we investigate the nonreciprocal circular dichroism for terahertz (THz) waves in magnetized InSb by the theoretical calculation and numerical simulation, which indicates that longitudinally magnetized InSb can be applied to the circular polarizer and nonreciprocal one-way transmission for the circular polarization THz waves. Furthermore, we propose a double-layer magnetoplasmonics based on the longitudinally magnetized InSb, and find two MO enhancement mechanisms in this device: the magneto surface plasmon resonance on the InSb-metal surface and Fabry–Pérot resonances between two orthogonal metallic gratings. These two resonance mechanisms enlarge the MO polarization rotation and greatly reduce the external magnetic field below 0.1T. The one-way transmission and perfect linear polarization conversion can be realized over 70dB, of which the transmittance can be modulated from 0 to 80% when the weak magnetic field changes from 0 to 0.1T under the low temperature around 200K. This magnetoplasmonic device has broad potential as a THz isolator, modulator, polarization convertor, and filter in the THz application systems.

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References

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Publication

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[Crossref]
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[Crossref] [PubMed]
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T. Arikawa, X. Wang, A. A. Belyanin, and J. Kono, “Giant tunable Faraday effect in a semiconductor magneto-plasma for broadband terahertz polarization optics,” Opt. Express 20(17), 19484–19492 (2012).
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2017 (1)

F. Fan, S. Chen, and S. J. Chang, “A review of magneto-optical microstructure devices at terahertz frequencies,” IEEE J. Sel. Top. Quantum Electron. 23(4), 1–11 (2017).
[Crossref]

2016 (1)

M. Tamagnone, C. Moldovan, J.-M. Poumirol, A. B. Kuzmenko, A. M. Ionescu, J. R. Mosig, and J. Perruisseau-Carrier, “Near optimal graphene terahertz non-reciprocal isolator,” Nat. Commun. 7, 11216 (2016).
[Crossref] [PubMed]

2015 (4)

S. Chen, F. Fan, X. Wang, P. Wu, H. Zhang, and S. Chang, “Terahertz isolator based on nonreciprocal magneto-metasurface,” Opt. Express 23(2), 1015–1024 (2015).
[Crossref] [PubMed]

F. Fan, X. Zhang, S. Li, D. Deng, N. Wang, H. Zhang, and S. Chang, “Terahertz transmission and sensing properties of microstructured PMMA tube waveguide,” Opt. Express 23(21), 27204–27212 (2015).
[Crossref] [PubMed]

S. Chen, F. Fan, X. He, M. Chen, and S. Chang, “Multifunctional magneto-metasurface for terahertz one-way transmission and magnetic field sensing,” Appl. Opt. 54(31), 9177–9182 (2015).
[Crossref] [PubMed]

D. Floess, J. Y. Chin, A. Kawatani, D. Dregely, H. U. Habermeier, T. Weiss, and H. Giessen, “Tunable and switchable polarization rotation with non-reciprocal plasmonic thin films at designated wavelengths,” Light Sci. Appl. 4(5), 257–277 (2015).
[Crossref]

2014 (2)

K. Lodewijks, N. Maccaferri, T. Pakizeh, R. K. Dumas, I. Zubritskaya, J. Akerman, P. Vavassori, and A. Dmitriev, “Magnetoplasmonic design rules for active magneto-optics,” Nano Lett. 14(12), 7207–7214 (2014).
[Crossref] [PubMed]

B. Hu, J. Tao, Y. Zhang, and Q. J. Wang, “Magneto-plasmonics in graphene-dielectric sandwich,” Opt. Express 22(18), 21727–21738 (2014).
[Crossref] [PubMed]

2013 (10)

F. Fan, S. Chen, X. H. Wang, and S. J. Chang, “Tunable nonreciprocal terahertz transmission and enhancement based on metal/magneto-optic plasmonic lens,” Opt. Express 21(7), 8614–8621 (2013).
[Crossref] [PubMed]

R. Shimano, G. Yumoto, J. Y. Yoo, R. Matsunaga, S. Tanabe, H. Hibino, T. Morimoto, and H. Aoki, “Quantum Faraday and Kerr rotations in graphene,” Nat. Commun. 4(5), 1841 (2013).
[Crossref] [PubMed]

G. Armelles, A. Cebollada, A. García-Martín, and M. U. González, “Magnetoplasmonics: combining magnetic and plasmonic functionalities,” Adv. Opt. Mat. 1(1), 10–35 (2013).
[Crossref]

A. K. Azad, J. F. O’Hara, R. Singh, and H. T. Chen, “A review of terahertz plasmonics in subwavelength holes on conducting films,” IEEE J. Sel. Top. Quantum Electron. 19(1), 8400416 (2013).
[Crossref]

M. Shalaby, M. Peccianti, Y. Ozturk, and R. Morandotti, “A magnetic non-reciprocal isolator for broadband terahertz operation,” Nat. Commun. 4(3), 1558 (2013).
[Crossref] [PubMed]

J. Y. Chin, T. Steinle, T. Wehlus, D. Dregely, T. Weiss, V. I. Belotelov, B. Stritzker, and H. Giessen, “Nonreciprocal plasmonics enables giant enhancement of thin-film Faraday rotation,” Nat. Commun. 4(3), 1599 (2013).
[Crossref] [PubMed]

L. E. Kreilkamp, V. I. Belotelov, J. Y. Chin, S. Neutzner, D. Dregely, T. Wehlus, I. A. Akimov, M. Bayer, B. Stritzker, and H. Giessen, “Waveguide-plasmon polaritons enhance transverse magneto-optical Kerr effect,” Phys. Rev. X 3(4), 041019 (2013).
[Crossref]

V. I. Belotelov, L. E. Kreilkamp, I. A. Akimov, A. N. Kalish, D. A. Bykov, S. Kasture, V. J. Yallapragada, A. Venu Gopal, A. M. Grishin, S. I. Khartsev, M. Nur-E-Alam, M. Vasiliev, L. L. Doskolovich, D. R. Yakovlev, K. Alameh, A. K. Zvezdin, and M. Bayer, “Plasmon-mediated magneto-optical transparency,” Nat. Commun. 4(7), 2128 (2013).
[PubMed]

F. Fan, S. Chen, W. Lin, Y. P. Miao, S. J. Chang, B. Liu, X. H. Wang, and L. Lin, “Magnetically tunable terahertz magnetoplasmons in ferrofluid-filled photonic crystals,” Appl. Phys. Lett. 103(16), 161115 (2013).
[Crossref]

Y. Zhou, X. Xu, H. Fan, Z. Ren, J. Bai, and L. Wang, “Tunable magnetoplasmons for efficient terahertz modulator and isolator by gated monolayer graphene,” Phys. Chem. Chem. Phys. 15(14), 5084–5090 (2013).
[Crossref] [PubMed]

2012 (4)

I. Crassee, M. Orlita, M. Potemski, A. L. Walter, M. Ostler, T. Seyller, I. Gaponenko, J. Chen, and A. B. Kuzmenko, “Intrinsic terahertz plasmons and magnetoplasmons in large scale monolayer graphene,” Nano Lett. 12(5), 2470–2474 (2012).
[Crossref] [PubMed]

H. Yan, Z. Li, X. Li, W. Zhu, P. Avouris, and F. Xia, “Infrared spectroscopy of tunable Dirac terahertz magneto-plasmons in graphene,” Nano Lett. 12(7), 3766–3771 (2012).
[Crossref] [PubMed]

A. Fallahi and J. Perruisseau-Carrier, “Manipulation of giant Faraday rotation in graphene metasurfaces,” Appl. Phys. Lett. 101(23), 231605 (2012).
[Crossref]

T. Arikawa, X. Wang, A. A. Belyanin, and J. Kono, “Giant tunable Faraday effect in a semiconductor magneto-plasma for broadband terahertz polarization optics,” Opt. Express 20(17), 19484–19492 (2012).
[Crossref] [PubMed]

2011 (4)

F. Fan, Z. Guo, J. Bai, X. Wang, and S. Chang, “Magnetic photonic crystals for terahertz tunable filter and multifunctional polarization controller,” J. Opt. Soc. Am. B 28(4), 697–702 (2011).
[Crossref]

A. M. Shuvaev, G. V. Astakhov, A. Pimenov, C. Brüne, H. Buhmann, and L. W. Molenkamp, “Giant magneto-optical faraday effect in HgTe thin films in the terahertz spectral range,” Phys. Rev. Lett. 106(10), 107404 (2011).
[Crossref] [PubMed]

H. J. Song and T. Nagatsuma, “Present and future of terahertz communications,” IEEE Trans. Terahertz Sci. Technol. 1(1), 256–263 (2011).
[Crossref]

V. I. Belotelov, I. A. Akimov, M. Pohl, V. A. Kotov, S. Kasture, A. S. Vengurlekar, A. V. Gopal, D. R. Yakovlev, A. K. Zvezdin, and M. Bayer, “Enhanced magneto-optical effects in magnetoplasmonic crystals,” Nat. Nanotechnol. 6(6), 370–376 (2011).
[Crossref] [PubMed]

2010 (1)

V. V. Temnov, G. Armelles, U. Woggon, D. Guzatov, A. Cebollada, A. Garcia-Martin, J. Garcia-Martin, T. Thomay, A. Leitenstorfer, and R. Bratschitsch, “Active magneto-plasmonics in hybrid metal–ferromagnet structures,” Nat. Photonics 4(2), 107–111 (2010).
[Crossref]

2009 (3)

Z. Wang, Y. Chong, J. D. Joannopoulos, and M. Soljacić, “Observation of unidirectional backscattering-immune topological electromagnetic states,” Nature 461(7265), 772–775 (2009).
[Crossref] [PubMed]

X. Wang, A. A. Belyanin, S. A. Crooker, D. M. Mittleman, and J. Kono, “Interference-induced terahertz transparency in a semiconductor magneto-plasma,” Nat. Phys. 6(2), 126–130 (2009).
[Crossref]

B. S. Passmore, D. G. Allen, S. R. Vangala, W. D. Goodhue, D. Wasserman, and E. A. Shaner, “Mid-infrared doping tunable transmission through subwavelength metal hole arrays on InSb,” Opt. Express 17(12), 10223–10230 (2009).
[Crossref] [PubMed]

2006 (2)

Z. Li, Y. Zhang, and B. Li, “Terahertz photonic crystal switch in silicon based on self-imaging principle,” Opt. Express 14(9), 3887–3892 (2006).
[Crossref] [PubMed]

H. T. Chen, W. J. Padilla, J. M. Zide, A. C. Gossard, A. J. Taylor, and R. D. Averitt, “Active terahertz metamaterial devices,” Nature 444(7119), 597–600 (2006).
[Crossref] [PubMed]

2005 (1)

J. Gómez Rivas, C. Janke, P. Bolivar, and H. Kurz, “Transmission of THz radiation through InSb gratings of subwavelength apertures,” Opt. Express 13(3), 847–859 (2005).
[Crossref] [PubMed]

2003 (1)

H. T. Chen, R. Kersting, and G. C. Cho, “Terahertz imaging with nanometer resolution,” Appl. Phys. Lett. 83(15), 3009–3011 (2003).
[Crossref]

Akerman, J.

Akimov, I. A.

Alameh, K.

Allen, D. G.

Aoki, H.

Arikawa, T.

Armelles, G.

G. Armelles, A. Cebollada, A. García-Martín, and M. U. González, “Magnetoplasmonics: combining magnetic and plasmonic functionalities,” Adv. Opt. Mat. 1(1), 10–35 (2013).
[Crossref]

Astakhov, G. V.

Averitt, R. D.

H. T. Chen, W. J. Padilla, J. M. Zide, A. C. Gossard, A. J. Taylor, and R. D. Averitt, “Active terahertz metamaterial devices,” Nature 444(7119), 597–600 (2006).
[Crossref] [PubMed]

Avouris, P.

H. Yan, Z. Li, X. Li, W. Zhu, P. Avouris, and F. Xia, “Infrared spectroscopy of tunable Dirac terahertz magneto-plasmons in graphene,” Nano Lett. 12(7), 3766–3771 (2012).
[Crossref] [PubMed]

Azad, A. K.

Bai, J.

Bayer, M.

Belotelov, V. I.

Belyanin, A. A.

Bolivar, P.

J. Gómez Rivas, C. Janke, P. Bolivar, and H. Kurz, “Transmission of THz radiation through InSb gratings of subwavelength apertures,” Opt. Express 13(3), 847–859 (2005).
[Crossref] [PubMed]

Bratschitsch, R.

Brüne, C.

Buhmann, H.

Bykov, D. A.

Cebollada, A.

G. Armelles, A. Cebollada, A. García-Martín, and M. U. González, “Magnetoplasmonics: combining magnetic and plasmonic functionalities,” Adv. Opt. Mat. 1(1), 10–35 (2013).
[Crossref]

Chang, S.

S. Chen, F. Fan, X. Wang, P. Wu, H. Zhang, and S. Chang, “Terahertz isolator based on nonreciprocal magneto-metasurface,” Opt. Express 23(2), 1015–1024 (2015).
[Crossref] [PubMed]

Chang, S. J.

F. Fan, S. Chen, and S. J. Chang, “A review of magneto-optical microstructure devices at terahertz frequencies,” IEEE J. Sel. Top. Quantum Electron. 23(4), 1–11 (2017).
[Crossref]

Chen, H. T.

H. T. Chen, W. J. Padilla, J. M. Zide, A. C. Gossard, A. J. Taylor, and R. D. Averitt, “Active terahertz metamaterial devices,” Nature 444(7119), 597–600 (2006).
[Crossref] [PubMed]

H. T. Chen, R. Kersting, and G. C. Cho, “Terahertz imaging with nanometer resolution,” Appl. Phys. Lett. 83(15), 3009–3011 (2003).
[Crossref]

Chen, J.

Chen, M.

Chen, S.

F. Fan, S. Chen, and S. J. Chang, “A review of magneto-optical microstructure devices at terahertz frequencies,” IEEE J. Sel. Top. Quantum Electron. 23(4), 1–11 (2017).
[Crossref]

S. Chen, F. Fan, X. Wang, P. Wu, H. Zhang, and S. Chang, “Terahertz isolator based on nonreciprocal magneto-metasurface,” Opt. Express 23(2), 1015–1024 (2015).
[Crossref] [PubMed]

Chin, J. Y.

Cho, G. C.

H. T. Chen, R. Kersting, and G. C. Cho, “Terahertz imaging with nanometer resolution,” Appl. Phys. Lett. 83(15), 3009–3011 (2003).
[Crossref]

Chong, Y.

Crassee, I.

Crooker, S. A.

Deng, D.

Dmitriev, A.

Doskolovich, L. L.

Dregely, D.

Dumas, R. K.

Fallahi, A.

A. Fallahi and J. Perruisseau-Carrier, “Manipulation of giant Faraday rotation in graphene metasurfaces,” Appl. Phys. Lett. 101(23), 231605 (2012).
[Crossref]

Fan, F.

F. Fan, S. Chen, and S. J. Chang, “A review of magneto-optical microstructure devices at terahertz frequencies,” IEEE J. Sel. Top. Quantum Electron. 23(4), 1–11 (2017).
[Crossref]

S. Chen, F. Fan, X. Wang, P. Wu, H. Zhang, and S. Chang, “Terahertz isolator based on nonreciprocal magneto-metasurface,” Opt. Express 23(2), 1015–1024 (2015).
[Crossref] [PubMed]

Fan, H.

Floess, D.

Gaponenko, I.

Garcia-Martin, A.

Garcia-Martin, J.

García-Martín, A.

G. Armelles, A. Cebollada, A. García-Martín, and M. U. González, “Magnetoplasmonics: combining magnetic and plasmonic functionalities,” Adv. Opt. Mat. 1(1), 10–35 (2013).
[Crossref]

Giessen, H.

Gómez Rivas, J.

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H. T. Chen, W. J. Padilla, J. M. Zide, A. C. Gossard, A. J. Taylor, and R. D. Averitt, “Active terahertz metamaterial devices,” Nature 444(7119), 597–600 (2006).
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Adv. Opt. Mat. (1)

G. Armelles, A. Cebollada, A. García-Martín, and M. U. González, “Magnetoplasmonics: combining magnetic and plasmonic functionalities,” Adv. Opt. Mat. 1(1), 10–35 (2013).
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Appl. Opt. (1)

Appl. Phys. Lett. (3)

A. Fallahi and J. Perruisseau-Carrier, “Manipulation of giant Faraday rotation in graphene metasurfaces,” Appl. Phys. Lett. 101(23), 231605 (2012).
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J. Opt. Soc. Am. B (1)

Light Sci. Appl. (1)

Nano Lett. (3)

H. Yan, Z. Li, X. Li, W. Zhu, P. Avouris, and F. Xia, “Infrared spectroscopy of tunable Dirac terahertz magneto-plasmons in graphene,” Nano Lett. 12(7), 3766–3771 (2012).
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M. Shalaby, M. Peccianti, Y. Ozturk, and R. Morandotti, “A magnetic non-reciprocal isolator for broadband terahertz operation,” Nat. Commun. 4(3), 1558 (2013).
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Nat. Nanotechnol. (1)

Nat. Photonics (1)

Nat. Phys. (1)

Nature (2)

H. T. Chen, W. J. Padilla, J. M. Zide, A. C. Gossard, A. J. Taylor, and R. D. Averitt, “Active terahertz metamaterial devices,” Nature 444(7119), 597–600 (2006).
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Opt. Express (8)

J. Gómez Rivas, C. Janke, P. Bolivar, and H. Kurz, “Transmission of THz radiation through InSb gratings of subwavelength apertures,” Opt. Express 13(3), 847–859 (2005).
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Fig. 1 (a) The real and imaginary parts of ε_L and (b) ε_R curves of longitudinally magnetized InSb in the THz regime under the different temperatures from 180 to 240K at the fixed external magnetic field of 0.3T; (c) The ε_L and (d) ε_R curves in the THz regime under the different magnetic field from 0.1 to 0.5 T at the fixed temperature of 200K.

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Fig. 2 Schematic diagram of nonreciprocal circular dichroism in the longitudinally magnetized InSb crystal. Both the light propagation and biased magnetic field directions are along the + z axis.

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Fig. 3 (a) Simulative transmission spectra of left-handed and (b) right-handed wave in longitudinally magnetized InSb in the THz regime under the different temperatures from 180 to 240K at 0.3T of the fixed external magnetic field along the + z axis; (c) Simulative transmission spectra of left-handed and (d) right-handed circular polarized wave under the different magnetic fields from 0.1 to 0.5 T along the + z axis at 200K of the fixed temperature.

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Fig. 4 The structure of the double-layer magnetoplasmonics. (a) 3D view; (b) Top view.

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Fig. 5 The working principle diagram of the double-layer magnetoplasmonics. (a) X-linear polarized wave and (b) Y-linear polarized wave are normally incident into the vertical grating surface of double-layer magnetoplasmonics. The external magnetic field is parallel to the direction of light propagation.

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Fig. 6 Simulative transmission spectra of double-layer magnetoplasmonics under the different magnetic fields at 180K. The X-linear polarized wave is normally incident into the positive surface of double-layer magnetoplasmonics. (a) Amplitude transmission spectra from 0.001 to 0.08T; (b) amplitude transmission spectra from 0.1 to 0.3T; (c) power transmission spectra from 0.01 to 0.08T; (d) power transmission spectra from 0.08 to 0.3T.

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Fig. 7 The simulative distribution of power flow density in the double-layer magneto-plasmonics at four frequencies of transmission peaks: P₀ = 0.38THz, P₁ = 0.6THz, P₂ = 0.9THz, P₃ = 1.22THz under 0.06T and 180K.

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Fig. 8 (a) The electirc field distributions in x-z cutting plane of the double-layer magneto-plasmonics at the frequencies of first four transmission peaks and two resonance dips under 0.06T and 180K. (b) The electirc field distributions of double-layer magneto-plasmonics in the 3D x-z cutting plane, input and output planes at the first transmission peak of 0.38THz.

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Fig. 9 (a) Power transmission spectra of double-layer magnetoplasmonics at the different temperatures under 0.06T. The X-linear polarized waves are normally incident into both the front and back surfaces of double-layer magnetoplasmonics, which are labeled by P (positive) and N (negative) to represent propagation directions in this figure. (b) Isolation spectra of the devices at the different temperatures under 0.05T calculated by the data from Fig. 9(a).

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Fig. 10 Transmission spectra of double-layer magnetoplasmonics with different structure geometry. (a) Varying the grating grid d width from 16 to 28μm with the fixed 100μm InSb length and 30μm grating period. (b) Varying the grating period a from 20 to 50 μm with the fixed grating grid gap 2μm and 100μm InSb length. (c) Varying the InSb length h from 50 to 100μm with the fixed 28μm grating grid width and 30μm grating period.

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Equations (10)

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[\begin{matrix} ε_{1} & - i ε_{2} & 0 \\ i ε_{2} & ε_{1} & 0 \\ 0 & 0 & ε_{3} \end{matrix}]

\begin{array}{l} ε_{1} = ε_{\infty} - \frac{ω_{p}^{2} (ω + γ i)}{ω [{(ω + γ i)}^{2} - ω_{c}^{2}]}, \\ ε_{2} = - \frac{ω_{p}^{2} ω_{c}}{ω [{(ω + γ i)}^{2} - ω_{c}^{2}]}, \\ ε_{3} = ε_{\infty} - \frac{ω_{p}^{2}}{ω (ω + γ i)} . \end{array}

N ({cm}^{-3}) = 5.76 \times 10^{14} T^{1.5} \times \exp [- 0.26 / (2 \times 8.625 \times 10^{- 5} \times T)] .

- β^{2} [\begin{matrix} E_{x} \\ E_{y} \\ E_{z} \end{matrix}] + [\begin{matrix} 0 \\ 0 \\ β^{2} E_{z} \end{matrix}] + ω^{2} μ_{0} ε_{0} [\begin{matrix} ε_{1} & - i ε_{2} & 0 \\ i ε_{2} & ε_{1} & 0 \\ 0 & 0 & ε_{3} \end{matrix}] \cdot [\begin{matrix} E_{x} \\ E_{y} \\ E_{z} \end{matrix}] = 0.

β_{1} = ω \sqrt{μ_{0} (ε_{1} - ε_{2})}, E_{y} = j E_{x}, E_{z} = 0,

β_{2} = ω \sqrt{μ_{0} (ε_{1} + ε_{2})}, E_{y} = - j E_{x}, E_{z} = 0

ω_{p 1} = \frac{\sqrt{ω_{c}^{2} + 4 ω_{p}^{2}} - ω_{c}}{2},

ω_{p 2} = \frac{\sqrt{ω_{c}^{2} + 4 ω_{p}^{2}} + ω_{c}}{2},

Δ ω_{p 2} = \frac{\sqrt{ω_{c}^{2} + 4 ω_{p}^{2}} - ω_{c}}{2}

4 n_{e f f} h = (m + 1) λ_{P m} (m = 1, 2, 3 \dots)