Publications
[1] M. Karimipour, M. B. Heydari, and I. Aryanian, “Broadband high-efficiency 3-bit coding metasurface in transmission mode based on the polarization conversion technique,” Scientific Reports, vol. 13, p. 11259, 2023.
[2] M. B. Heydari, M. Karimipour, and M. Mohammadi Shirkolaei, “Analytical study of highly adjustable plasmonic modes in graphene-based heterostructure for THz applications,” Journal of Optics, vol. 52, pp. 1912-1918, 2023/12/01 2023.
[3] M. B. Heydari, M. M. Shirkolaei, and M. Karimipour, “Theoretical analysis of hybrid surface plasmon polaritons in plasma-based elliptical structures with graphene layers for THz applications,” The European Physical Journal D, vol. 77, p. 58, 2023/04/07 2023.
[4] M. B. Heydari, M. M. Shirkolaei, and M. Karimipour, “Hybrid Plasma-Graphene Elliptical Structures: An Analytical Approach,” 2023.
[5] M. B. Heydari, M. M. Shirkolaei, and M. Karimipour, “Hybrid Surface Plasmon Polaritons (HSPPs) in Plasma-based Elliptical Waveguides with Graphene Layers,” arXiv preprint arXiv:2303.08192, 2023.
[6] M. B. Heydari, M. Karimipour, and M. Mohammadi Shirkolaei, “High-performance hyperbolic phonon-plasmon modes at mid-infrared frequencies in grounded graphene-hBN heterostructures: an analytical approach,” Optical and Quantum Electronics, vol. 55, p. 128, 2023.
[7] M. B. Heydari, M. Karimipour, and M. M. Shirkolaei, “Theoretical Investigation of Adjustable Plasmonic Modes in Graphene-based Heterostructures in THz Range: Transfer Matrix Method,” 2023.
[8] M. B. Heydari, M. Karimipour, and M. M. Shirkolaei, “New Analytical Approach Based on Transfer Matrix Method (TMM) for Study of Tunable Plasmonic Modes in Graphene-Based Heterostructures,” arXiv preprint arXiv:2301.00807, 2023.
[9] M. B. Heydari, M. Karimipour, and M. M. Shirkolaei, “Highly Confined and Tunable Mid-IR Polaritonics in Symmetric Nonlinear-Graphene-hBN Heterostructures,” Plasmonics, vol. 17, pp. 2269-2283, 2022.
[10] M. B. Heydari, M. Karimipour, and M. M. Shirkolaei, “Strong Phonon-Plasmon Coupling in Grounded Graphene-Hexagonal Boron Nitride (hBN) Heterostructures,” 2022.
[11] M. B. Heydari, M. Karimipour, and M. M. Shirkolaei, “Hyperbolic Phonon-Plasmon Modes in Grounded Graphene-hBN Heterostructures for Mid-Infrared Applications,” arXiv preprint arXiv:2211.03701, 2022.
[12] M. B. Heydari, M. Karimipour, and M. M. Shirkolaei, “Tunable Plasmon-Phonon Modes in Nonlinear-Graphene-hBN Heterostructures,” 2022.
[13] M. B. Heydari, M. Karimipour, and M. M. Shirkolaei, “Analytical Study of Hybrid Surface Phonon-Plasmon-Polaritons (HSP3) in Symmetric Nonlinear-Graphene-hBN Heterostructures,” arXiv preprint arXiv:2210.10141, 2022.
[14] M. B. Heydari, “Tunable SPPs in graphene-based cylindrical structures with gyroelectric layers,” Optik, vol. 254, p. 168651, 2022.
[15] M. B. Heydari, “Tunable SPPs supported by hybrid graphene-gyroelectric waveguides: an analytical approach,” Optical and Quantum Electronics, vol. 54, p. 136, 2022.
[16] M. B. Heydari, “Highly Confined Mid-infrared Plasmonics in Graphene-plasma Cylindrical Structures,” 2022.
[17] M. B. Heydari, “Novel Theoretical Study of Plasmonic Waves in Graphene-based Cylindrical Waveguides with Gyro-electric Layers,” arXiv preprint arXiv:2201.10421, 2022.
[18] M. B. Heydari, “Tunable Plasmonic Modes in Graphene-loaded Plasma Media,” 2022.
[19] M. B. Heydari, “Hybrid Graphene-Gyroelectric Structures: A Novel Platform for THz Applications,” arXiv preprint arXiv:2201.06538, 2022.
[20] M. B. Heydari and M. H. V. Samiei, “Analytical Study of TM-Polarized Surface Plasmon Polaritons in Nonlinear Multi-Layer Graphene-Based Waveguides”, Plasmonics, vol. 16, pp. 841-848, 2021.
[21] M. B. Heydari and M. H. V. Samiei, “Three-port Terahertz Circulator with Multi-layer Triangular Graphene-Based Post”, Optik, vol. 231, p. 166457, 2021.
[22] M. B. Heydari, “Analytical Study of TE-Polarized SPPs in Nonlinear Multi-Layer Graphene-Based Structures,” Plasmonics, vol. 16, pp. 2327-2334, 2021.
[23] M. B. Heydari, “TE-Polarized SPPs in Nonlinear Multi-layer Graphene-Based Structures,” 2021.
[24] M. B. Heydari, “TE-Polarized Surface Plasmon Polaritons (SPPs) in Nonlinear Multi-layer Graphene-Based Waveguides: An Analytical Model,” arXiv preprint arXiv:2107.01684, 2021.
[25] M. B. Heydari and M. H. V. Samiei, “Analytical Investigation of Magneto-Plasmons in Anisotropic Multi-layer Planar Waveguides Incorporating Magnetically Biased Graphene Sheets,” arXiv preprint arXiv:2103.11452, 2021.
[26] M. B. Heydari and M. H. V. Samiei, “Magneto-Plasmons in Grounded Graphene-Based Structures with Anisotropic Cover and Substrate,” arXiv preprint arXiv:2103.08557, 2021.
[27] M. B. Heydari and M. H. V. Samiei, “Anisotropic Multi-layer Cylindrical Structures Containing Graphene Layers: An Analytical Approach,” arXiv preprint arXiv:2103.05594, 2021.
[28] M. B. Heydari and M. H. V. Samiei, “Anisotropic Multi-layer Elliptical Waveguides Incorporating Graphene Layers: A Novel Analytical Model,” arXiv preprint arXiv:2103.01925, 2021.
[29] M. B. Heydari and M. H. V. Samiei, “Grounded Graphene-Based Nano-Waveguide with Chiral Cover and Substrate: New Theoretical Investigation,” arXiv preprint arXiv:2102.12465, 2021.
[30] M. B. Heydari and M. H. V. Samiei, “Chiral multi-layer waveguides incorporating graphene sheets: an analytical approach,” arXiv preprint arXiv:2102.10135, 2021.
[31] M. B. Heydari and M. H. V. Samiei, “A Novel Graphene-Based Circulator with Multi-layer Triangular Post for THz Region,” arXiv preprint arXiv:2102.02683, 2021.
[32] M. B. Heydari and M. H. V. Samiei, “TM-polarized Surface Plasmon Polaritons in Nonlinear Multi-layer Graphene-Based Waveguides: An Analytical Study,” arXiv preprint arXiv:2101.02536, 2021.
[33] M. B. Heydari and M. H. Vadjed Samiei, “An Analytical Study of Magneto-Plasmons in Anisotropic Multi-layer Structures Containing Magnetically Biased Graphene Sheets,” Plasmonics, vol. 15, pp. 1183-1198, 2020.
[34] M. B. Heydari and M. H. V. Samiei, “Analytical Study of Chiral Multi-Layer Structures Containing Graphene Sheets for THz Applications,” IEEE Transactions on Nanotechnology, vol. 19, pp. 653-660, 2020.
[35] M. B. Heydari and M. H. V. Samiei, “A Novel Analytical Study of Anisotropic Multi-Layer Elliptical Structures Containing Graphene Layers,” IEEE Transactions on Magnetics, vol. 56, pp. 1-10, 2020.
[36] M. B. Heydari and M. H. V. Samiei, “Novel analytical model of anisotropic multi-layer cylindrical waveguides incorporating graphene layers,” Photonics and Nanostructures-Fundamentals and Applications, vol. 42, p. 100834, 2020.
[37] M. B. Heydari and M. H. V. Samiei, “New analytical investigation of anisotropic graphene nano-waveguides with bi-gyrotropic cover and substrate backed by a PEMC layer,” Optical and Quantum Electronics, vol. 52, p. 108, 2020.
[38] M. B. Heydari and M. H. Vadjed Samiei, “Analytical study of hybrid surface plasmon polaritons in a grounded chiral slab waveguide covered with graphene sheet,” Optical and Quantum Electronics, vol. 52, p. 406, 2020.
[39] M. B. Heydari and A. Ahmadvand, “A novel analytical model for a circularly-polarized, ferrite-based slot antenna by solving an integral equation for the electric field on the circular slot,” Waves in Random and Complex Media, pp. 1-20, 2020.
[40] M. B. Heydari and M. H. V. Samiei, “Graphene-Based Couplers: A Brief Review,” arXiv preprint arXiv: 2010.09462, 2020.
[41] M. B. Heydari and M. H. V. Samiei, “A Short Review on Graphene-Based Filters: Perspectives and Challenges,” arXiv preprint arXiv: 2010.07176, 2020.
[42] M. B. Heydari and M. H. V. Samiei, “A Short Review of Plasmonic Graphene-Based Resonators: Recent Advances and Prospects,” arXiv preprint arXiv: 2011.14767, 2020.
[43] A. Ahmadvand, M. B. Heydari, B. Rejaei, and J. Ghalibafan, “Analytical calculation for input impedance of a circularly‐polarized ferrite disk antenna including higher order modes,” International Journal of RF and Microwave Computer‐Aided Engineering, vol. 29, p. e21783, 2019.
[44] M. B. Heydari, M. Asgari, and A. Keshtkar, “A Novel Structure of Augmented Railgun Using Multilayer Magnets and Sabots,” IEEE Transactions on Plasma Science, vol. 47, pp. 3320-3326, 2019.
[45] M. B. Heydari and M. H. V. Samiei, “Plasmonic graphene waveguides: A literature review,” arXiv preprint arXiv: 1809.09937, 2018.