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1. Radio-transparent dipole antenna based on a metasurface cloak

   https://doi.org/10.1038/s41467-022-28714-w  

   Soric, Jason; Ra’di, Younes; Farfan, Diego; Alù, Andrea (December 2022, Nature Communications)

   Abstract Antenna technology is at the basis of ubiquitous wireless communication systems and sensors. Radiation is typically sustained by conduction currents flowing around resonant metallic objects that are optimized to enhance efficiency and bandwidth. However, resonant conductors are prone to large scattering of impinging waves, leading to challenges in crowded antenna environments due to blockage and distortion. Metasurface cloaks have been explored in the quest of addressing this challenge by reducing antenna scattering. However, metasurface-based designs have so far shown limited performance in terms of bandwidth, footprint and overall scattering reduction. Here we introduce a different route towards radio-transparent antennas, in which the cloak itself acts as the radiating element, drastically reducing the overall footprint while enhancing scattering suppression and bandwidth, without sacrificing other relevant radiation metrics compared to conventional antennas. This technique opens opportunities for cloaking technology, with promising features for crowded wireless communication platforms and noninvasive sensing. 

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2. Mantle Cloaking for Decoupling of Interleaved Phased Antenna Arrays in 5G Applications

   S. Pawar, H. M. (September 2020, METANANO-2020)

   null (Ed.)

   The concept of mantle cloaking is applied to suppress the undesired cross-coupling among the antenna elements of two tightly spaced and interleaved phased antenna arrays used in 5G wireless applications, which in turn enhances the radiation characteristics of the arrays. It is demonstrated that the specifically designed metasurface cloaks decouple the antenna elements of two different arrays and enable to restore the original radiation patterns of the isolated arrays, such that the antenna arrays placed in close proximity of each other can radiate independently for a wide range of beam scanning angles. This paper illustrates microstrip antenna arrays with elliptically shaped metasurface cloaks integrated in printed technology. The simulation results validate the fact that by encasing the elements of the arrays with their respective cloaks, it is not only possible to eliminate the cross coupling but also to restore the radiation properties of the antenna arrays within the frequency bands of their operation. 

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3. Decoupling and Cloaking of Rectangular and Circular Patch Antennas and Interleaved Antenna Arrays with Planar Coated Metasurfaces at C-Band Frequencies—Design and Simulation Study

   https://doi.org/10.3390/s24010291  

   Pawar, Shefali; Lee, Doojin; Skinner, Harry; Suh, Seong-Youp; Yakovlev, Alexander (January 2024, Sensors)

   An electromagnetic cloaking approach is employed with the intention to curb the destructive effects of mutual interference for rectangular and circularly shaped patch antennas situated in a tight spacing. Primarily, we show that by coating the top surface of each patch with an appropriately designed metasurface, the mutual coupling is considerably reduced between the antennas. Furthermore, the cloak construct is extended to a tightly spaced, interleaved linear patch antenna array configuration and it is shown that the coated metasurfaces successfully enhance the performance of each array in terms of their matching characteristics, total efficiencies and far-field realized gain patterns for a broad range of beam-scan angles. For rectangular patches, the cloaked Array I and II achieve corresponding peak total efficiencies of 93% and 90%, in contrast to the total efficiencies of 57% and 21% for uncloaked Array I and II, respectively, at their operating frequencies. Moreover, cloaked rectangular Array I and II exhibit main lobe gains of 13.2 dB and 13.8 dB, whereas uncloaked Array I and II only accomplish main lobe gains of 10 dB and 5.5 dB, respectively. Likewise, for the cloaked circular patches, corresponding total efficiencies of 91% and 89% are recorded for Array I and II, at their operating frequencies (uncloaked Array I and II show peak efficiencies of 71% and 55%, respectively). The main lobe gain for each cloaked circular patch array is approximately 14.2 dB, whereas the uncloaked Array I and II only achieve maximum gains of 10.5 dB and 7.5 dB, respectively. 

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4. Elliptical Metasurface Cloaks for Decoupling and Cloaking of Microstrip Monopole Antennas at 28 GHz and 39 GHz for 5G Wireless Applications

   https://doi.org/10.1109/IEEECONF35879.2020.9329717  

   Pawar, Shefali; Mastromatteo, Salvatore; Yakovlev, Alexander B.; Bernety, Hossein Mehrpour; Skinner, Harry G.; Suh, Seong-Youp; Alu, Andrea (July 2020, 2020 IEEE AP-S/URSI Conference)

   null (Ed.)

   In order to curtail mutual coupling between two closely spaced microstrip monopole antennas operating at frequencies 28 GHz and 39 GHz, the concept of electromagnetic cloaking is applied by utilizing elliptical metasurfaces. In this paper, we show that by enveloping the monopole antennas with the specifically engineered metasurface cloaks, not only is there a significant reduction in the mutual electromagnetic interaction but also restoration in the radiation patterns are observed, as if the antennas were completely isolated from each other. The decoupling effect is seen in the reduction of mutual S-parameters. This enables the antennas to radiate independently even though they are placed in a very close proximity. 

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5. Solution‐Processed Ti ₃ C ₂ T _x MXene Antennas for Radio‐Frequency Communication

   https://doi.org/10.1002/adma.202003225  

   Han, Meikang; Liu, Yuqiao; Rakhmanov, Roman; Israel, Christopher; Tajin, Md_Abu_Saleh; Friedman, Gary; Volman, Vladimir; Hoorfar, Ahmad; Dandekar, Kapil_R; Gogotsi, Yury (November 2020, Advanced Materials)

   Abstract Highly integrated, flexible, and ultrathin wireless communication components are in significant demand due to the explosive growth of portable and wearable electronic devices in the fifth‐generation (5G) network era, but only conventional metals meet the requirements for emerging radio‐frequency (RF) devices so far. Here, it is reported on Ti₃C₂T_xMXene microstrip transmission lines with low‐energy attenuation and patch antennas with high‐power radiation at frequencies from 5.6 to 16.4 GHz. The radiation efficiency of a 5.5 µm thick MXene patch antenna manufactured by spray‐coating from aqueous solution reaches 99% at 16.4 GHz, which is about the same as that of a standard 35 µm thick copper patch antenna at about 15% of its thickness and 7% of the copper weight. MXene outperforms all other materials evaluated for patch antennas to date. Moreover, it is demonstrated that an MXene patch antenna array with integrated feeding circuits on a conformal surface has comparable performance with that of a copper antenna array at 28 GHz, which is a target frequency in practical 5G applications. The versatility of MXene antennas in wide frequency ranges coupled with the flexibility, scalability, and ease of solution processing makes MXene promising for integrated RF components in various flexible electronic devices. 

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