Printed Four Key‐Device Units for Unified Platform of Wireless Anti‐Counterfeiting Label to Bridge in Blockchain

Sun, Junfeng; Parajuli, Sajjan; Shrestha, Kiran; Park, Jinhwa; Shrestha, Sagar; Jung, Younsu; Park, Hyejin; Koirala, Gyan Raj; Nasir, Nadra; Kim, Seongryeong; Truong, Han; Jang, Haesook; Lee, Jinkwan; Lee, Jong-Chan; Cho, Gyoujin

doi:10.1002/admt.202100969

Cited by 11 publications

(9 citation statements)

References 31 publications

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Section: Printed Electronics Techniques Applications In Energy Harves...mentioning

confidence: 99%

“…[158] However, the usual method of combining printing techniques that utilize similar layer thicknesses is a direct print of layers one-by-one, sometimes with an interlayer, to avoid material mixing. [159] The right choice of technique and material allows printed electronics techniques to be used in unusual applications, e.g., to make functional electrical connections on temperature-sensitive surfaces [160] or to produce structures with temperature-sensitive geometries. [161] Application area of printed electronics includes but is not limited to displays, [162][163][164] sensors, [165][166][167] electronic components, [168,169] and wearables.…”

Section: Printed Electronicsmentioning

confidence: 99%

“…Fully printed rectennas can be used in various applications, e.g., a smart packaging or biosensor. Sun et al [159] gravureprinted the anticounterfeiting label integrating printed four keydevice units, a 13.56 MHz rectenna, supercapacitors, a 1-bit code generator chip, and quick response code. The R2R printing process was performed in a cleanroom at 6 m min −1 speed, followed by curing at 150 °C.…”

Section: Antennas In Near-field Applicationsmentioning

confidence: 99%

mentioning

confidence: 99%

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Printed Electronics in Radiofrequency Energy Harvesters and Wireless Power Transfer Rectennas for IoT Applications

Skarżyński

Słoma

2023

Adv Elect Materials

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The Internet of Things is currently one of the fastest-growing branches in electronics. The development of energy storage systems and the miniaturization of dedicated printed circuit boards significantly influence that growth. However, the need for batteries and traditional printed circuit boards still limits devices' minimum size, weight, and cost, narrowing the application area. Energy harvesters and wireless power transfer systems fabricated with printed electronics can significantly reduce such devices' weight, size, and cost. Printed electronics technology provides scalable tools for many electronics applications, shortening the validation time and enabling new low-cost or disposable solutions on lightweight and flexible substrates embedded inside 3D printed structures and directly on device housings. Energy harvesting and wireless power transfer systems in electronic devices can provide enough power to minimize battery capacity and size or even eliminate the need for batteries in low-power applications. This review presents an adaptation of printed electronics technology in the fabrication of radio frequency energy harvesters and wireless power transfer rectennas for IoT applications. Last, perspectives for development towards greater integration with microsystems, transient electronics with ecofriendly materials, adaptation for next-generation telecommunication systems, and 3D structural electronics solutions are briefly discussed.

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Section: Printed Electronics Techniques Applications In Energy Harves...mentioning

confidence: 99%

Section: Printed Electronicsmentioning

confidence: 99%

Section: Antennas In Near-field Applicationsmentioning

confidence: 99%

mentioning

confidence: 99%

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Printed Electronics in Radiofrequency Energy Harvesters and Wireless Power Transfer Rectennas for IoT Applications

Skarżyński

Słoma

2023

Adv Elect Materials

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“…Counterfeiting has been a global, long-lasting, and unsolved issue that permeates virtually every field of our society from the luxury goods industry to pharmaceuticals. Over the years, various anticounterfeiting strategies including holography ( 1 , 2 ), watermarks ( 3 , 4 ), barcodes ( 5 , 6 ), quick response codes ( 7 , 8 ), and radio frequency identification (RFID) tags ( 9 , 10 ) have been developed, offering competitive countermeasures against growing fraudulent practices worldwide. Many of these anticounterfeiting technologies, however, are based on deterministic encoding mechanism that has inherent vulnerability to various cloning attacks.…”

Section: Introductionmentioning

confidence: 99%

Integrating biopolymer design with physical unclonable functions for anticounterfeiting and product traceability in agriculture

et al. 2023

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Smallholder farmers and manufacturers in the Agri-Food sector face substantial challenges because of increasing circulation of counterfeit products (e.g., seeds), for which current countermeasures are implemented mainly at the secondary packaging level, and are generally vulnerable because of limited security guarantees. Here, by integrating biopolymer design with physical unclonable functions (PUFs), we propose a cryptographic protocol for seed authentication using biodegradable and miniaturized PUF tags made of silk microparticles. By simply drop casting a mixture of variant silk microparticles on a seed surface, tamper-evident PUF tags can be seamlessly fabricated on a variety of seeds, where the unclonability comes from the stochastic assembly of spectrally and visually distinct silk microparticles in the tag. Unique, reproducible, and unpredictable PUF codes are generated from both Raman mapping and microscopy imaging of the silk tags. Together, the proposed technology offers a highly secure solution for anticounterfeiting and product traceability in agriculture.

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Inkjet‐Printed Metal Oxide/PEDOT:PSS‐Based Diodes and Rectifiers for Wireless Power Transfer

Singh,

Priyadarisini,

Pradhan

et al. 2023

Adv Eng Mater

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Printed electronic circuits are beginning to attract commercial success in different area of applications that include low‐cost wearables, biosensors, biomedical tags, packaging, e‐textiles etc. However, the major part of the research in this domain has always been focused at developing high performance thin film transistors (TFTs), while the other essential circuit elements, that are required, for example, for low‐loss conversion of the input power, have rarely been reported. In this regard, we demonstrate inkjet‐printed amorphous oxide based diodes on glass, and flexible polyimide substrates with rectification ratio >104 and operation frequency up to 25 MHz, and 15 MHz, respectively. Next, using the printed diodes full‐wave and double half‐wave rectifiers have been fabricated to convert input AC signals to DC supply. In addition, we demonstrate wireless power transfer (WPT), where the input AC signal has been wirelessly transmitted from a distance of 3 cm, at 125 kHz. The demonstrated WPT technology can be suitable for invasive implantable devices and stand‐alone systems in multiple mediums. Lastly, bending fatigue tests have been carried out with the printed diodes on flexible substrates, down to a bending radius of 2.5 mm to demonstrate tensile strain tolerance up to 2.5%.This article is protected by copyright. All rights reserved.

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Printed Four Key‐Device Units for Unified Platform of Wireless Anti‐Counterfeiting Label to Bridge in Blockchain

Cited by 11 publications

References 31 publications

Printed Electronics in Radiofrequency Energy Harvesters and Wireless Power Transfer Rectennas for IoT Applications

Printed Electronics in Radiofrequency Energy Harvesters and Wireless Power Transfer Rectennas for IoT Applications

Integrating biopolymer design with physical unclonable functions for anticounterfeiting and product traceability in agriculture

Inkjet‐Printed Metal Oxide/PEDOT:PSS‐Based Diodes and Rectifiers for Wireless Power Transfer

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