Graphene‐Based Microwave Metasurfaces and Radio‐Frequency Devices

Zhang, Jin; Zhu, Weiren

doi:10.1002/adpr.202100142

Cited by 22 publications

(11 citation statements)

References 110 publications

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“…From DC to microwave frequencies, for typical values of µ c , the energy of the electromagnetic waves is insufficient to promote an electron from the valence band to the conduction band (interband transition) and the following condition exists ℏω < 2|µ c | [24]- [27]. Therefore, for the purpose of this work, in expression (1) it is possible to neglect the interband conductivity term and express the dynamic conductivity of graphene only through the contribution of intra-band conductivity which can be expressed as [26]:…”

Section: A Graphene Transport Properties At Rf and Microwavementioning

confidence: 99%

High-sensitivity narrow-band CSRR-based Microwave Sensor for Monitoring Glucose Level

Pecorella

Verderame

Lombardo

et al. 2022

2022 IEEE International Instrumentation and Measurement Technology Conference (I2MTC)

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Exhaled breath can be used for early detection and diagnosis of diseases, monitoring metabolic activity, and precision medicine. In this work, we design and simulate a microwave sensor in which thin graphene aerogels are integrated into rectangular microwave waveguides. Graphene aerogels are ideal sensing platforms for gases and volatile compounds as they combine extremely high surface-to-volume ratio and good electrical conductivity at RF and microwave frequencies. The latter is modified by exposure to different gases, and -when integrated into a waveguide-these changes result in significant shifts in transmission and reflection scattering parameters. We model the aerogel as a graphene grid with hexagonal openings of size 22.86x10.16x0.1 mm 3 , characterized by an air volume equal to about 90% of its entire volume. This grid is used as a building block for modeling thicker samples (up to 9 mm). To simulate the variation in the dynamic conductivity of the graphene sheets as a consequence of the absorption of gaseous molecules, a sweep of the chemical potential from 0.0 eV to 0.5 eV with steps of 0.1 eV was used. The results show a significant variation of the waveguide transmission scattering parameters resulting from the gas-induced modification of the graphene conductivity, and hence the potential of the proposed sensor design for breath analysis.

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Section: A Graphene Transport Properties At Rf and Microwavementioning

confidence: 99%

High-sensitivity narrow-band CSRR-based Microwave Sensor for Monitoring Glucose Level

Pecorella

Verderame

Lombardo

et al. 2022

2022 IEEE International Instrumentation and Measurement Technology Conference (I2MTC)

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“…[ 24 ] In addition, some kinds of tunable RAs through combining graphene with an active metasurface has been reported. [ 25–31 ] In these kinds of hybrid structures, graphene is used only as an amplitude‐tuning layer by changing its effective sheet resistance, while frequency or phase is tuned still by controlling semiconductor devices including PIN diodes loaded in a periodic metallic metasurface, in which designing the feeding network to provide electrical excitation for lumped components such as varactor diodes and PIN diodes is still a complex task. Meanwhile, these tunable RAs including active semiconductor are bulky and not able to planarization, which is difficultly bent to conform with the carrier.…”

Section: Introductionmentioning

confidence: 99%

“…[24] In addition, some kinds of tunable RAs through combining graphene with an active metasurface has been reported. [25][26][27][28][29][30][31] In these kinds of hybrid structures, graphene is used only as an amplitude-tuning layer by changing its effective sheet resistance, while frequency or phase is tuned still by controlling semiconductor devices including PIN diodes loaded in a periodic metallic metasurface, in which designing Flexible and tunable radar absorbers (RAs) are in great demand both in stealth technologies and electromagnetic delusion for concealment of complex targets such as aircraft and unmanned aerial vehicle from radar detection. As a general approach, conventional lumped components such as varactor diodes and resistors are employed to achieve frequency and/or amplitude tunability of RAs.…”

mentioning

confidence: 99%

Flexible and Dual‐Tunable Radar Absorber Enabled by Graphene

Geng

Liu

Chen

et al. 2022

Adv Materials Technologies

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Flexible and tunable radar absorbers (RAs) are in great demand both in stealth technologies and electromagnetic delusion for concealment of complex targets such as aircraft and unmanned aerial vehicle from radar detection. As a general approach, conventional lumped components such as varactor diodes and resistors are employed to achieve frequency and/or amplitude tunability of RAs. However, despite the intricate feeding networks and complex fabrication processes, this approach shows great difficulty in integrating the conventional rigid components with flexible substrate. Hence, it is an enormous challenge to realize both dual‐tunable and flexible RAs. Here the authors for the first time design and experimentally characterize a flexible and dual‐tunable RA with independent control of the frequency and amplitude. Most important is that the achieving both amplitude and frequency control is fully based on the tunability of graphene, without any lumped devices and intricate feeding network, and even without any metal involved. Hence, this dual‐tunable RA shows the priority of being flexible, light weight, and environmentally friendly. Although the prototype in this work is operating in microwave spectrum, the tunable functionalities at millimeter or terahertz spectral bands can also be obtained due to the intrinsic tunability of graphene.

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“…Metasurfaces have recently garnered extensive research attention owing to their excellent properties, such as their low profile, 4,5 lightweight structure, 6 and easy conformability 7,8 . There are many ongoing studies regarding various types of metasurfaces, including absorptive, 9 frequency selective, 10 absorptive/transmissive, 11,12 and phase cancelation metasurfaces, 13 among others 14 . Once these metasurfaces are designed and fabricated, their performances cannot be changed, and as a result, they are not adaptable in complex and changeable environments.…”

Section: Introductionmentioning

confidence: 99%

“…7,8 There are many ongoing studies regarding various types of metasurfaces, including absorptive, 9 frequency selective, 10 absorptive/transmissive, 11,12 and phase cancelation metasurfaces, 13 among others. 14 Once these metasurfaces are designed and fabricated, their performances cannot be changed, and as a result, they are not adaptable in complex and changeable environments.…”

Section: Introductionmentioning

confidence: 99%

Design of a switchable phase‐modulated metasurface with wide modulation bandwidth in S band

Guo

Chen

Liu

et al. 2022

Int J RF Mic Comp-Aid Eng

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This article presents a switchable phase‐modulated metasurface (PMM) whose reflection phase can be modulated between two states using PIN diodes. The PMM is composed of a switchable surface loaded with four PIN diodes in each unit cell, as well as a ground plane and an air spacer. The reflection phase can be modulated when the PIN diodes are switched between two states (ON and OFF). Theoretical analysis indicates that the phase‐modulation bandwidth is determined by the thickness of the PMM. The phase‐modulation bandwidth with a phase difference of 180 ± 37° achieves 2.6–4.25 GHz and a fractional bandwidth of 48.2%.

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Graphene‐Based Microwave Metasurfaces and Radio‐Frequency Devices

Cited by 22 publications

References 110 publications

High-sensitivity narrow-band CSRR-based Microwave Sensor for Monitoring Glucose Level

High-sensitivity narrow-band CSRR-based Microwave Sensor for Monitoring Glucose Level

Flexible and Dual‐Tunable Radar Absorber Enabled by Graphene

Design of a switchable phase‐modulated metasurface with wide modulation bandwidth in S band

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