Antenna of silver nanoparticles mounted on a flexible polymer substrate constructed using inkjet print technology

Matyas, Jiri; Münster, Lukáš; Olejník, Robert; Vlcek, Karel; Slobodian, Petr; Krčmář, Petr; Urbánek, Pavel; Kuřitka, Ivo

doi:10.7567/jjap.55.02bb13

Cited by 14 publications

(15 citation statements)

References 29 publications

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“…The print process conditions were set as follows: the cartridge temperature was 35 °C and the substrate temperature was 45 °C in order to achieve a good sintering of a drop on the substrate. After the printing process the antenna was dried in a vacuum oven at 120 °C for 20 minutes in order to sinter the nanoparticles and create a compact layer [10][11][12][13][14][15][16]. 2.…”

Section: Experimental Methodsmentioning

confidence: 99%

Microstrip antenna from silver nanoparticles printed on a flexible polymer substrate

Matyas

Slobodian

Münster

et al. 2017

Materials Today: Proceedings

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This work describes the use of inkjet printing technology to fabricate a flexible microstrip antenna. The antenna is printed on a flexible PET foil (Polyethylene terephthalate) using silver nanoparticles. Silver nanoparticles were synthetized by the solvothermal precipitation technique. The diameter of the prepared silver nanoparticles ranges from 20 to 200 nm measured with the help of the SEM analysis. In addition, the ink formulation for printing of a homogenous and electrically conductive layer was further prepared using silver nanoparticles. The printed antenna operates in two frequency bands of 2.02 GHz (-16.02 db) and 2.3 GHz (-19.33 db). The antenna is flexible and weigh is only 0.208 g and is suitable for electronic devices of a very low weight, such as wearable electronic devices.

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Section: Experimental Methodsmentioning

confidence: 99%

Microstrip antenna from silver nanoparticles printed on a flexible polymer substrate

Matyas

Slobodian

Münster

et al. 2017

Materials Today: Proceedings

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show abstract

“…More specifically in the case of radiating elements, different approaches to implementing antennas on flexible substrates have been explored, such as the use of liquid metals for 2D [11] and 3D [12] antennas, the use of flexible microwave grade substrates with conventional machine milling techniques to implement conformal antennas [13,14,15], the use of textile substrates [16] or the use of conductive fibers [17]. Radiating elements can also be implemented by making use of the deposition of conductive/functional inks and pastes, using inkjet approaches, in which silver or silver chloride inks are employed owing to the balance between high conductivity, deposition feasibility and certain biocompatibility [18,19,20,21,22,23,24,25,26]. Radiating elements have been implemented using inkjet techniques for low cost Radio Frequency Identification RFID applications on paper substrates [19,20], flexible plastic substrates such as Kapton [21], radiating elements over ultra-thin substrates [22], complex radiating elements based on fractal patterns [23], millimeter wave flexible antennas [24] or volumetric antennas and lenses based on the inkjet fabrication process.…”

Section: Introductionmentioning

confidence: 99%

“…Radiating elements can also be implemented by making use of the deposition of conductive/functional inks and pastes, using inkjet approaches, in which silver or silver chloride inks are employed owing to the balance between high conductivity, deposition feasibility and certain biocompatibility [18,19,20,21,22,23,24,25,26]. Radiating elements have been implemented using inkjet techniques for low cost Radio Frequency Identification RFID applications on paper substrates [19,20], flexible plastic substrates such as Kapton [21], radiating elements over ultra-thin substrates [22], complex radiating elements based on fractal patterns [23], millimeter wave flexible antennas [24] or volumetric antennas and lenses based on the inkjet fabrication process. The proposed studies, however, do not exploit the use of screen-printing techniques for the implementation of radiating elements within the microwave frequency range, nor are system level tests performed on the proposed prototypes.…”

Section: Introductionmentioning

confidence: 99%

Implementation of Radiating Elements for Radiofrequency Front-Ends by Screen-Printing Techniques for Internet of Things Applications

Picallo

Klaina

López-Iturri

et al. 2019

Sensors

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The advent of the Internet of Things (IoT) has led to embedding wireless transceivers into a wide range of devices, in order to implement context-aware scenarios, in which a massive amount of transceivers is foreseen. In this framework, cost-effective electronic and Radio Frequency (RF) front-end integration is desirable, in order to enable straightforward inclusion of communication capabilities within objects and devices in general. In this work, flexible antenna prototypes, based on screen-printing techniques, with conductive inks on flexible low-cost plastic substrates is proposed. Different parameters such as substrate/ink characteristics are considered, as well as variations in fabrication process or substrate angular deflection in device performance. Simulation and measurement results are presented, as well as system validation results in a real test environment in wireless sensor network communications. The results show the feasibility of using screen-printing antenna elements on flexible low-cost substrates, which can be embedded in a wide array of IoT scenarios.

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“…Refs. [10,11,12,13] using engineered conductive inks made from silver nanoparticles, carbon nanotubes, or organometallic particles [14]. At the beginning this technology required thermal sintering at a high temperature, but now, due to developments in material science, new types of conductive ink have been developed which dry instantly at room temperature [11].…”

Section: Introductionmentioning

confidence: 99%

Flexible Radio-Frequency Identification (RFID) Tag Antenna for Sensor Applications

Islam

Yahya

Cho

2018

Sensors

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In this paper, an inkjet-printed flexible Radio-Frequency Identification (RFID) tag antenna is proposed for an ultra-high frequency (UHF) sensor application. The proposed tag antenna facilitates a system-level solution for low-cost and faster mass production of RFID passive tag antenna. The tag antenna consists of a modified meander line radiator with a semi-circular shaped feed network. The structure is printed on photo paper using silver nanoparticle conductive ink. The generic design outline, as well as tag antenna performances for several practical application aspects are investigated. The simulated and measured results verify the coverage of universal UHF RFID band with an omnidirectional radiation pattern and a long-read range of 15 ft. In addition, the read range for different bending angles and lifetimes of the tag antenna are also demonstrated.

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Antenna of silver nanoparticles mounted on a flexible polymer substrate constructed using inkjet print technology

Cited by 14 publications

References 29 publications

Microstrip antenna from silver nanoparticles printed on a flexible polymer substrate

Microstrip antenna from silver nanoparticles printed on a flexible polymer substrate

Implementation of Radiating Elements for Radiofrequency Front-Ends by Screen-Printing Techniques for Internet of Things Applications

Flexible Radio-Frequency Identification (RFID) Tag Antenna for Sensor Applications

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