Restricted accessResearch articleFirst published online 2025-2
Polarization-insensitive,negative indexed inverted U-shaped flexible metamaterial absorber based on microstructure resonator for multi-band energy harvesting
This article presents a polarization-insensitive, negative indexed inverted U-shaped flexible metamaterial absorber based on a microstructure resonator for multi-band energy harvester application. The vertical inverted U-shaped joint and central split ring resonator together create significant resonance covering three consecutive L-, S-, and C-band absorption peaks for four resonance frequencies: 1.975 GHz with 99.99% absorption, 2.85 GHz with 99.28% absorption, 5.265 GHz with 96.79% absorption, and 5.5 GHz with 89.12% absorption. The design has a rare double negative metamaterial feature at 5.265 GHz, while a balanced geometrical appearance that is polarization insensitive for θ and φ improved the structure’s durability and tunability. Finite computer simulation technology was used to simulate and examine the mechanisms involved in absorption at 1— 6 GHz. Based on Rogers RO4350 B and copper, the structural design showed excellent absorption for 15° and 30° bends and 2 × 4, 4 × 8 arrays with an efficiency of 96.38% at an incidence angle of 30° in transverse magnetic mode, a 3x 3 array was developed for energy harvesting. For energy harvesting applications using array structure, the efficiency parameter is unnoted in most of the reported articles. Moreover, the array demonstrated polarization insensitivity for both transverse electric and transverse magnetic modes at angles of 0°, 30°, and 60°. The proposed quad-band absorber shows significant potential for energy harvesting applications.
HossainMBFaruqueMRIIslamMT, et al.Triple band microwave metamaterial absorber based on double E-shaped symmetric split ring resonators for EMI shielding and stealth applications. J Mater Res Technol2022; 18: 1653–1668.
2.
BilottiFNucciLVegniL. An SRR based microwave absorber. Microw Opt Technol Lett2006; 48: 2171–2175.
3.
ChowdhuryMZBIslamMTAlzamilA, et al.A tunable star-shaped highly sensitive microwave sensor for solid and liquid sensing. Alex Eng J2024; 86: 644–662.
4.
MusaAHakimMLAlamT, et al.Permeability negative split square resonator for solid materials dielectric constant and aqueous solution pH sensing applications. Sensor Actuator Phys2024; 369: 115107.
5.
HanifAHakimMLAlamT, et al.Polarization insensitive oblique incident angle stable ultra-thin nano ring resonator-based metamaterial absorber for visible and near-infrared region applications. Opt Laser Technol2023; 164: 109494.
6.
ZhouYLCaoXYGaoJ, et al.Broadband aperture‐coupling patch antenna with improved radiation and scattering performance based on metamaterial absorber. IET Microw, Antennas Propag2019; 13: 875–880.
7.
VafapourZTroyWRashidiA. Colon cancer detection by designing and analytical evaluation of a water-based THz metamaterial perfect absorber. IEEE Sensor J2021; 21: 19307–19313.
8.
MisranNYusopSHIslamMT, et al.Analysis of parameterization substrate thickness and permittivity for concentric split ring square reflectarray element. Jurnal Kejuruteraan2011; 23: 11–15.
9.
VafapourZ. Cost-effective bull’s eye aperture-style multi-band metamaterial absorber at sub-THz band: design, numerical analysis, and physical interpretation. Sensors2022; 22: 2892.
10.
ZhengRLiuYLingL, et al.Ultra wideband tunable terahertz metamaterial absorber based on single-layer graphene strip. Diam Relat Mater2024; 141: 110713.
11.
ÖzerZAkdoğanVWangL, et al.Graphene-based tunable metamaterial absorber for terahertz sensing applications. Plasmonics2024: 1–11.
12.
ErrajrajiKDasSJebborN, et al.Design of an ultra-thin quad-band metamaterial absorber for sensing and antenna performance enhancement. Measurement2024; 242: 116027.
13.
SakibSHoqueARahimSKBA, et al.A central spiral split rectangular-shaped metamaterial absorber surrounded by polarization-insensitive ring resonator for S-band applications. Materials2023; 16: 1172.
14.
RifatAARahmaniMXuL, et al.Hybrid metasurface based tunable near-perfect absorber and plasmonic sensor. Materials2018; 11: 1091.
15.
SolimanMMIslamMTAlamT, et al.Broadband near unity absorption meta-structure for solar thermophotovoltaic systems and optical window applications. Nanoscale2023.
16.
MajeedKNiaziSAAltintasO, et al.Polarization-insensitive ultra-wideband metamaterial absorber for C-and X-bands. Plasmonics2024; 19: 2507–2516.
17.
DincerFKaraaslanMColakS, et al.Multi-band polarization independent cylindrical metamaterial absorber and sensor application. Mod Phys Lett B2016; 30: 1650095.
18.
VafapourZLariESForouzeshfardMR. Breast cancer detection capability of a tunable perfect semiconductor absorber: analytical and numerical evaluation. Opt Eng2021; 60: 107101.
19.
XuZ-x.MengH-y.ChenA, et al.Tunable low-frequency and broadband acoustic metamaterial absorber. J Appl Phys2021; 129.
20.
ZarastvandMGhassabiMTalebitootiR. Prediction of acoustic wave transmission features of the multilayered plate constructions: a review. Jnl of Sandwich Structures Materials2022; 24: 218–293.
21.
ZarastvandMGhassabiMTalebitootiR. A review approach for sound propagation prediction of plate constructions. Arch Comput Methods Eng2021; 28: 2817–2843.
22.
ZarastvandMGhassabiMTalebitootiR. Acoustic insulation characteristics of shell structures: a review. Arch Comput Methods Eng2021; 28: 505–523.
23.
TalebitootiRZarastvandM. The effect of nature of porous material on diffuse field acoustic transmission of the sandwich aerospace composite doubly curved shell. Aero Sci Technol2018; 78: 157–170.
24.
Asadi JafariMHZarastvandMZhouJ. Doubly curved truss core composite shell system for broadband diffuse acoustic insulation. J Vib Control2023: 10775463231206229.
25.
AlmoneefTSErkmenFRamahiOM. Harvesting the energy of multi-polarized electromagnetic waves. Sci Rep2017; 7: 14656.
26.
LiuCDuanGZhangB, et al.Precisely nanofabricated cross shaped metamaterial absorbers for nearly perfect solar energy harvesting. Appl Energy2024; 372: 123807.
27.
BağmancıMWangLSabahC, et al.Broadband multi‐layered stepped cone shaped metamaterial absorber for energy harvesting and stealth applications. Engineering Reports2024; 6: e12903.
28.
MazaheriMHMaabHRahimAA. Graphene-based metamaterial absorber for energy harvesting in the Terahertz range. J Opt2024: 1–11.
29.
JahanMIFaruqueMRIAl-MugrenK. Polarization-incident angle independent metamaterial wave absorber for enhanced electromagnetic energy harvesting in ultraviolet-B, visible spectrum, and near-infrared frequency range. Mater Today Commun2024; 38: 108229.
30.
UllahNIslamMSHoqueA, et al.An efficient, compact, wide-angle, wide-band, and polarization-insensitive metamaterial electromagnetic energy harvester. Alex Eng J2023; 82: 377–388.
31.
HuWYangZZhaoF, et al.Low-cost air gap metasurface structure for high absorption efficiency energy harvesting. Int J Antenn Propag2019; 2019: 1–8.
32.
Umaña-IdarragaFCataño-OchoaDMontoya-VilladaS, et al.Design of a perfect and multi-resonant metamaterial absorber for electromagnetic energy harvesting applications. J Phys : Conf Ser2021; 2118: 012005.
33.
SmithDRSchultzSMarkošP, et al.Determination of effective permittivity and permeability of metamaterials from reflection and transmission coefficients. Phys Rev B2002; 65: 195104.
HannanSIslamMTSolimanMS, et al.A co-polarization-insensitive metamaterial absorber for 5G n78 mobile devices at 3.5 GHz to reduce the specific absorption rate. Sci Rep2022; 12: 11193.
36.
AbdelazizAShohdyAMohammedSA, et al.Reducing radar cross section through absorption metamaterial antenna for concealment and detection applications. AEU-International Journal of Electronics and Communications2024; 178: 155260.
37.
AvitzourYUrzhumovYAShvetsG. Wide-angle infrared absorber based on a negative-index plasmonic metamaterial. Phys Rev B2009; 79: 045131.
38.
HannanSIslamMTAlmalkiSH, et al.Rotational symmetry engineered, polarization and incident angle-insensitive, perfect metamaterial absorber for X and Ku band wireless applications. Sci Rep2022; 12: 3740.
BilalMSaleemRAbbasiQH, et al.Miniaturized and flexible FSS-based EM shields for conformal applications. IEEE Trans Electromagn C2020; 62: 1703–1710.
41.
GhoshJDuttaRSarkhelA, et al.Design of miniaturize flexible wideband frequency selective surface for electromagnetic shielding application. Waves Random Complex Media2022: 1–21.
42.
ShuvoMMKHossainMIRahmanS, et al.A wide-angle, enhanced oblique incidence, bend-able metamaterial absorber employed in visible region with a sun shape resonator. IEEE Access2021; 9: 126466–126480.
43.
ErcanMTetikGAltintasO, et al., “Dual-band metamaterial-based energy harvesting application for WLAN communication frequency bands,” 2022.
44.
XieFYangG-MGeyiW. Optimal design of an antenna array for energy harvesting. IEEE Antenn Wireless Propag Lett2013; 12: 155–158.
45.
HakimMLAlamTSolimanMS, et al.Polarization insensitive symmetrical structured double negative (DNG) metamaterial absorber for Ku-band sensing applications. Sci Rep2022; 12: 479.
46.
de AraújoJBOSiqueiraGLKemptnerE, et al.An ultrathin and ultrawideband metamaterial absorber and an equivalent-circuit parameter retrieval method. IEEE Trans Antenn Propag2020; 68: 3739–3746.
47.
HannanSIslamMTAlmutairiAF, et al.Wide bandwidth angle-and polarization-insensitive symmetric metamaterial absorber for X and Ku band applications. Sci Rep2020; 10: 10338.
