Properties of Polysiloxane/Nanosilica Nanodielectrics for Wearable Electronic Devices

Radu, Elena; Panaitescu, Denis Mihaela; Andrei, Laura; Ciuprina, Florin; Nicolae, Cristian Andi; Gabor, Augusta Raluca; Trușcă, Roxana

doi:10.3390/nano12010095

Cited by 4 publications

(2 citation statements)

References 58 publications

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“…Also, a low-loss tangent is needed to decrease the amount of signal attenuation [12,13]. On the other hand, high mechanical flexibility, low thermal expansion coefficient, high thermal conductivity, and lightweight, among other features, are required for the materials to meet the needs of the soft and rubbery electronic industry [14][15][16][17]. Consequently, 5G technology will facilitate Internet of Things (IoT) applications such as wireless communication, automotive, biomedical, aerospace, electronic eye cameras, flexible sensors, and body-worn antennas.…”

Section: Introductionmentioning

confidence: 99%

Silicone rubber‐nanoceramic composites for 5G antenna substrates

Altalebi,

Atiyah,

Farid

2023

The Journal of Engineering

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Here, the eligibility of silicone rubber‐nanoceramic composites as flexible substrates for sub‐6 GHz 5G antennas is investigated. Two different composites are prepared using the solution mixing method, namely mono and hybrid composites. The reflection and transmission coefficient (S‐parameters) of composites are measured using a rectangular waveguide‐based transmission line technique in conjunction with a Vector Network Analyzer (VNA) at C‐band frequencies (4–8 GHz). The Nicolson–Ross–Weir (NRW) algorithm is adopted to extract the complex permittivity and loss tangent of the material under test. Due to the synergetic effect, the silicone rubber hybrid composite (0.12BiVO4+0.12LaNbO4) exhibits the advantage of a lowered loss tangent while retaining a good dielectric constant at 5.78 GHz. A rectangular microstrip patch antenna is designed and simulated with CST software using 0.12BVO/0.12LNO/0.76SR composite as a substrate. Moreover, based on the simulation, the antenna with the proposed substrate has acceptable performance at 5.78 GHz with the return loss, directivity, and gain of −25.05 dB, 5.46 dBi and 2.74 dBi, respectively. As a result, the composite material's ability to act as a suitable substrate for a 5 GHz Wi‐Fi antenna is confirmed.

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Section: Introductionmentioning

confidence: 99%

Silicone rubber‐nanoceramic composites for 5G antenna substrates

Altalebi,

Atiyah,

Farid

2023

The Journal of Engineering

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“…There are various techniques of determining the dielectric characteristics of textiles that are included in [23]. Furthermore, microstrip patch antennas provide numerous advantages for on-body wearable electronics in addition to their directivity advantages [24]- [26]. The three most important advantages are: simplicity of design, low cost and the decrease in the amount of energy used by the skin all of which are attributed to the ground plane, which is between the radiating component and the surface and offers separation [27].…”

Section: Introductionmentioning

confidence: 99%

Wearable Textile Patch Antenna: Challenges and Future Directions

et al. 2022

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Wearable antennas have grown in popularity in recent years as a result of their appealing features and prospects to actualize lightweight, compact, low-cost and adaptable wireless communications and surroundings. These antennas have to be conformal and made of lightweight materials in a low-profile arrangement when attached to various parts of the human body. Near-body operation of these antennas should be possible without degradation. When these characteristics are taken into account, the layout of wearable antennas become challenging, especially when textile substrates are investigated, high conductivity materials are used during manufacturing procedures and body binding scenarios have an impact on the design's performance. Several of these issues arise in the context of body-worn deployment, despite modest changes in magnitude between implementations. This paper examines the multiple issues and obstacles encountered in the construction of wearable antennas as well as the range of materials used, and the Specific Absorption Rate (SAR) effects employed as well as the bending scheme. An overview of the innovative features and their separate approaches to addressing the difficulties lately raised by work in this field conducted by the scientific community is provided as an appendix.

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