1. Veselago V. G. (1967). Electrodynamics of substances with simultaneously negative values of ε and μ. Uspekhi fizicheskih nauk, Vol. 92. [in Russian language]
2. Lagar'kov A. N., Kisel' V. N., Sarychev A. K., Semenenko V. N. (2010). Electrophysics and electrodynamics of metamaterials. Teplofizika vysokih temperatur, Vol. 48, (6), pp. 1031 – 1048. [in Russian language]
3. Lagar'kov A. N., Kisel' V. N., Sarychev A. K., Semenenko V. N. Electrophysics and electrodynamics of metamaterials. Institute of Theoretical and Applied Electrodynamics RAS. Available at: http://www.itae.ru/science/ topics/№1%20(метаматериалы).pdf (Accessed: 31.10.2020) [in Russian language]
4. Vendik I. B., Vendik O. G. (2013). Metamaterials and their application in microwave technology (Review). Zhurnal tekhnicheskoy fiziki, Vol. 83, (1), pp. 3 – 28. [in Russian language]
5. Slyusar V. (2010). Metamaterials in antenna technology: basic principles and results. Pervaya milya, (3–4), pp. 44 – 60. [in Russian language]
6. Balabuha N. P., Bashirin A. A., Semenenko V. N. (2009). Effect of back radiation of electromagnetic waves by a waveguide structure made of a metamaterial. Pis'ma v Zhurnal eksperimental'noy i teoreticheskoy fiziki, Vol. 89, (10), pp. 593 – 598. [in Russian language]
7. Mitrohin V. N., Ryzhenko D. S., Tyagunov V. A. (2011). Experimental studies of microwave devices containing metamaterials. Fizika volnovyh protsessov i radiotekhnicheskie sistemy, Vol. 14, (3), pp. 43 – 53. [in Russian language]
8. Pendry J. B., Holden A. J., Robbins D. J., Stewart W. J. (1999). Magnetism from conductors and enhanced nonlinear phenomena. IEEE Transactions on Microwave Theory and Techniques, Vol. 47, (11), pp. 2075 – 2084. DOI 10.1109/22.798002.
9. Ran L., Huangfu J., Chen H. et al. (2005). Experimental Study on Several Left-Handed Metamaterials. Progress in Electromagnetics Research, Vol. 51, pp. 249 – 279. DOI 10.2528/PIER04040502.
10. Smith D. R., Schultz S., Markos P., Soukoulis C. M. (2002). Determination of effective permittivity and permeability of metamaterials from reflection and transmission coefficients. Physical Review B, Vol. 65. DOI https://doi.org/10.1103/PhysRevB.65.195104.
11. Smith D. R., Vier D. C., Koschny Th., Soukoulis C. M. (2005). Electromagnetic parameter retrieval from inhomogeneous metamaterials. Physical Review E, Vol. 71. DOI https://doi.org/10.1103/PhysRevE.71.036617.
12. Smith D. R., Gollub J., Mock J. J. et al. (2006). Calculation and Measurement of Bianisotropy in a Split Ring Resonator Metamaterial. Journal of Applied Physics, Vol. 100. Available at: https://doi.org/10.1063/1.2218033
13. Sikder Sunbeam Islam, Mohammad Rashed Iqbal Faruque, Mohammad Tariqul Islam. (2014). The Design and Analysis of a Novel Split-H-Shaped Metamaterial for Multi-Band Microwave Applications. Materials, 7(7), pp. 4994 – 5011. DOI https://doi.org/10.3390/ma7074994.
14. Simovski C., Belov P. A., He S. (2003). Backward Wave Region and Negative Material Parameters of a Structure Formed by Lattices of Wires and Split-Ring Resonators. IEEE Transaction on Antennas and Propagation, Vol. 51, pp. 2582 – 2345. DOI 10.1109 / TAP.2003.817554.
15. Lubkowski G., Schuhmann R., Weiland T. (2007). Extraction of Effective Metamaterial Parameters by Parameter Fitting of Dispersive Models. Microwave and Optical Technology Letters, Vol. 49, (2), pp. 285 – 288. DOI https://doi.org/10.1002/mop.22105.
16. Kaz'min A. I., Fedyunin P. A. (2021). Control of electrophysical parameters of metamaterials by the method of surface electromagnetic waves. Defektoskopiya, (4), pp. 51 – 67. [in Russian language]
17. Kaz'min A. I. (2021). Multifrequency Optimization Method for Measuring Frequency Dependences of Electrophysical Parameters of Dielectric and Magnetodielectric Coatings. Izmeritel'naya tekhnika, (9), pp. 54 – 61. [in Russian language]