Abstract
This paper investigates polarization insensitive multiple band Metamaterial Absorber (MA). The proposed MA is a splitted circular ring acting as outer structure and inner structure is a type of four fan blade. The metallic resonating structure is mounted over a dielectric substrate (FR-4), which is covered by complete ground plane. The structure yields thirteen independent high absorption peaks (>80%) over the range of interest. The absorption peaks are at 1.50, 2.92, 3.88, 4.84, 5.50, 7.09, 7.65, 8.54, 8.81, 9.26, 9.90, 11.69 and 12.02 GHz with absorptivity of 88.58, 98.27, 80.62, 88.76, 91.32, 81.74, 81.21, 88.47, 81.95, 96.16, 98.67, 98.58 and 96.26% respectively. The metamaterial behaviour of the structure is proven by plotting real & imaginary part of permittivity (ε) & permeability (μ) and normalized impedance (Z). Further, to explain absorption mechanism, the current distribution is plotted at the front and back side of the structure for an independent frequency belongs to L, C, S and X band spectrum. The polarization insensitive behaviour of the structure is studied under different angles for normal and oblique incidence. The structure proposed is compared with the previously reported multi band absorbers and it is found that proposed absorbers have more numbers of absorption peaks and cover frequency spectrum such as L, C S and X band simultaneously. The proposed multi band absorber finds practical applications in the field of IoT, Bio Medical sensing applications, Energy harvesting, Radar cross section reduction, Military applications, back lobe reductions in case of antenna, satellite communication, WI-FI devise and many more.
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Abbreviations
- Metamaterial Absorber:
-
MA
- Electromagnetic:
-
EM
- Split Ring Resonator :
-
SRR
- Double Negative :
-
DNG
- Left Handed Material :
-
LHM
- Transverse Electric :
-
TE
- Transverse Magnetic :
-
TM
- Finite Element Method :
-
FEM
References
Abu-Hamdeh NH, Alazwari MA, Salilih EM, Sajadi SM, Karimipour A (2021) Improve the efficiency and heat transfer rate’trend prediction of a flat-plate solar collector via a solar energy installation by examine the Titanium Dioxide/Silicon Dioxide-water nanofluid. Sustain Energy Technol Assessments 48:101623
Abusorrah AM, Mebarek-Oudina F, Ahmadian A, Baleanu D (2021) Modeling of a MED-TVC desalination system by considering the effects of nanoparticles: energetic and exergetic analysis. J Therm Anal Calorim 144(6):2675–2687
Al-badri KSL (2019) Multi band metamaterials absorber for stealth applications. Revista Eletronica Gestão & Saúde 11(1):133–144
Al-Badri KSL, Alwan YS, Khalaf MF (2021) Ultra-thin dual-band perfect metamaterials absorber for microwave applications. Materials Today: Proceedings 42:2164–2168
Alkurt FO, Altintas O, Atci A, Bakir M, Unal E, Akgol O, Delihacioglu K, Karaaslan M, Sabah C (2018) Antenna-based microwave absorber for imaging in the frequencies of 1.8, 2.45, and 5.8 GHz. Opt Eng 57(11):113102
Ariyo DO, Bello-Ochende T (2020) Critical heat fluxes for subcooled flow boiling in optimised microchannels. Int J Hydromechatronics 3(2):140–154
Asgharian R, Zakeri B, Karimi O (2018) Modified hexagonal triple-band metamaterial absorber with wide-angle stability. AEU-Int J Electron Commun 87:119–123
Bakır M, Karaaslan M, Karadağ F, Ünal E, Akgöl O, Alkurt FÖ, Sabah C (2018) Metamaterial-based energy harvesting for GSM and satellite communication frequency bands. Opt Eng 57(8):087110
Barde C, Choubey A, Sinha R (2019) Wide band metamaterial absorber for Ku and K band applications. J Appl Phys 126(17):175104
Barde C, Choubey A, Sinha R (2020) A set square design metamaterial absorber for X-band applications. J Electromagn Waves Appl 34(10):1430–1443
Barde C, Choubey A, Sinha R, Mahto SK, Ranjan P (2020) A compact wideband metamaterial absorber for Ku band applications. J Mater Sci Mater Electron 31(19):16898–16906
Bilal RMH, Baqir MA, Choudhury PK, Ali MM, Rahim AA, Kamal W (2020) Polarization-insensitive multi-band metamaterial absorber operating in the 5G spectrum. Optik 216:164958
Chaurasiya D, Ghosh S, Bhattacharyya S, Srivastava KV (2015) An ultrathin quad-band polarization-insensitive wide-angle metamaterial absorber. Microw Opt Technol Lett 57(3):697–702
Chen HT, Padilla WJ, Cich MJ, Azad AK, Averitt RD, Taylor AJ (2009) A metamaterial solid-state terahertz phase modulator. Nat Photonics 3(3):148–151
Cheng Y, Zou Y, Luo H, Chen F, Mao X (2019) Compact ultra-thin seven-band microwave metamaterial absorber based on a single resonator structure. J Electron Mater 48(6):3939–3946
Farhan M, Zurni O, Mebarek-Oudina F, Raza J, Shah Z, Choudhari RV, Makinde OD (2020) Implementation of the one-step one-hybrid block method on the nonlinear equation of a circular sector oscillator. Comput Math Model 31(1):116–132
Gao XJ, Cai T, Zhu L (2016) Enhancement of gain and directivity for microstrip antenna using negative permeability metamaterial. AEU-Int J Electron Commun 70(7):880–885
Guo H-H, Bajuri MY, Alrabaiah H, Muhammad T, Sajadi SM, Ghaemi F, Baleanu D, Karimipour A (2021) The investigation of energy management and atomic interaction between coronavirus structure in the vicinity of aqueous environment of H2O molecules via molecular dynamics approach. J Mol Liq 341:117430
Hameed MH, Shawkat SA, Al-badri KSL (2020) Multi bands metamaterial absorber optimized by genetic algorithm in microwave regime. In: AIP conference proceedings. AIP publishing LLC, vol 2213, no. 1, p 020055
Hannan S, Islam MT, Sahar NM, Mat K, Chowdhury ME, Rmili H (2020) Modified-segmented split-ring based polarization and angle-insensitive multi-band metamaterial absorber for X, Ku and K band applications. IEEE Access 8:144051–144063
Hannan S, Islam MT, Soliman MS, Sahar NBM, Singh MSJ, Faruque MRI, Alzamil A (2022) A filling-factor engineered, perfect metamaterial absorber for multiple applications at frequencies set by IEEE in C and X Bands. Journal of Materials Research and Technology, A filling-factor engineered, perfect metamaterial absorber for multiple applications at frequencies set by IEEE in C and X bands
Ji S, Jiang C, Zhao J, Zhang X, He Q (2019) Design of a polarization-insensitive triple-band metamaterial absorber. Opt Commun 432:65–70
Landy NI, Sajuyigbe S, Mock JJ, Smith DR, Padilla WJ (2008) Perfect metamaterial absorber. Phys Rev Lett 100(20):207402
Munaga P, Bhattacharyya S, Ghosh S, Srivastava KV (2018) An ultra-thin compact polarization-independent hexa-band metamaterial absorber. Applied Physics A 124(4):1–12
Ni B, Wang ZY, Zhao RS, Ma XY, Xing ZQ, Yang LS, Huang LJ, Lin YY, Zhang DB (2017) Realisation of a humidity sensor based on perfect metamaterial absorber. Opt Quant Electron 49(1):33
Pendry JB (2000) Negative refraction makes a perfect lens. Phys Rev Lett 85(18):3966
Persis GE, Paul JJ, Mary TB, Joy RC (2022) A compact tilted split ring multiband metamaterial absorber for energy harvesting applications. Materials Today: Proceedings 56:368–372
Ranjan P, Choubey A, Mahto SK, Sinha R (2018) An ultrathin five-band polarization insensitive metamaterial absorber having hexagonal array of 2D-bravais-lattice. Prog Electromagn Res 87:13–23
Ranjan P, Choubey A, Mahto SK, Sinha R (2018) A six-band ultra-thin polarization-insensitive pixelated metamaterial absorber using a novel binary wind driven optimization algorithm. Journal of Electromagnetic Waves and Applications 32(18):2367–2385
Rawa MJH, Abu-Hamdeh NH, Karimipour A, Nusier OK, Ghaemi F, Baleanu D (2022) Phase change material dependency on solar power plant building through examination of energy-saving. J Energy Storage 45:103718
Roy K, Sinha R, Das D, Choubey A, Barde C, Ranjan P, Kumar S (2022) A recent survey on zeroth-order resonant (ZOR) antennas. Analog Integr Circ Sig Process:1–18
Roy K, Sinha R, Barde C (2022) Linear-to-linear polarization conversion using metasurface for X, Ku and K band applications. Frequenz 76:461–470
Safa M, Ahmadi M, Mehrmashadi J, Petkovic D, Mohammadhassani M, Zandi Y, Sedghi Y (2020) Selection of the most influential parameters on vectorial crystal growth of highly oriented vertically aligned carbon nanotubes by adaptive neuro-fuzzy technique. Int J Hydromechatronics 3(3):238–251
Sarkhel A, Chaudhuri SRB (2017) Compact quad-band polarization-insensitive ultrathin metamaterial absorber with wide angle stability. IEEE Antennas Wirel Propag Lett 16:3240–3244
Schurig D, Mock JJ, Justice BJ, Cummer SA, Pendry JB, Starr AF, Smith DR (2006) Metamaterial electromagnetic cloak at microwave frequencies. Science 314(5801):977–980
Smith DR, Padilla WJ, Vier DC, Nemat-Nasser SC, Schultz S (2000) Composite medium with simultaneously negative permeability and permittivity. Phys Rev Lett 84(18):4184–4187
Song J, Wang L, Li M, Dong J (2018) A dual-band metamaterial absorber with adjacent absorption peaks. J Phys D Appl Phys 51(38):385105
Sun S, He Q, Xiao S, Xu Q, Li X, Zhou L (2012) Gradient-index meta-surfaces as a bridge linking propagating waves and surface waves. Nat Mater 11(5):426–431
Tee KF (2020) The influence of water on frequency response of concrete plates armed by nanoparticles utilising analytical approach. Int J Hydromechatronics 3(1):51–68
Tran CM, Van Pham H, Nguyen HT, Nguyen TT, Vu LD, Do TH (2019) Creating multiband and broadband metamaterial absorber by multiporous square layer structure. Plasmonics 14(6):1587–1592
Wang AX, Qu SB, Yan MB, Wang WJ, Wang JF, Zheng L, Wang JL (2019) Six-band polarization-insensitive perfect metamaterial absorber using L-shaped resonators. Applied Physics A 125(5):1–7
Zafar MF, Masud U (2021) A multiple-bands metamaterial absorber based in X, Ku and K-Band. https://doi.org/10.21203/rs.3.rs-425882/v1
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Roy, K., Barde, C., Ranjan, P. et al. A wide angle polarization insensitive multi-band metamaterial absorber for L, C, S and X band applications. Multimed Tools Appl 82, 9399–9411 (2023). https://doi.org/10.1007/s11042-022-13740-z
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DOI: https://doi.org/10.1007/s11042-022-13740-z