Your search keyword '"Conductive ink"' showing total 44 results

1. Electrochemical Determination of Catechol Using a Disposable Printed Electrode with Conductive Ink Based on Graphite and Carbon Black

Author

Sthephane Pereira de Oliveira, Thaís Cristina de Oliveira Cândido, Arnaldo César Pereira, and Daniela Nunes da Silva

Subjects

conductive ink, electrochemical sensor, catechol, water, carbon black, graphite, Analytical chemistry, QD71-142

Abstract

Catechol (CT) is a phenolic compound widely used in various industrial sectors, but it is toxic; thus, there is a need for methods that aim to identify and quantify the existence of residues of this material in the environment. In this study a disposable printed electrochemical sensor was developed as an effective alternative for determining CT in water samples. The electrode, called SPEC, was manufactured using the screen-printing method using polyethylene terephthalate (PET) as a support, in which a conductive ink based on carbonaceous materials was used to print the working and auxiliary electrodes and a silver/silver chloride of ink on the reference electrode. The optimal ratio for the conductive ink was 6.25% carbon black, 35.42% graphite, and 58.33% nail polish. The ink obtained was characterized by scanning electron microscopy (SEM). The assessment of the effect of pH on the redox process showed Nernstian behavior (0.057 V pH−1), indicating that the process involves the same number of protons and electrons. Under optimized conditions, with 0.2 mol L−1 acetate buffer at pH 5.0, and by square wave voltammetry, the sensor presented sensitivity values of 0.31 μA L μmol−1, a detection limit of 5.96 μmol L−1, and a quantification limit of 19.87 μmol L−1. The sensor was applied to determine CT in tap water samples, and the results showed recoveries between 97.95 and 100.17%.

Published

2024

2. Development and Characterization of Conductive Ink Composed of Graphite and Carbon Black for Application in Printed Electrodes

Author

Thaís Cristina de Oliveira Cândido, Arnaldo César Pereira, and Daniela Nunes da Silva

Subjects

conductive ink, carbon black, graphite, nail polish, screen-printed electrodes, Analytical chemistry, QD71-142

Abstract

This work developed a conductive ink composed of carbonaceous material for printing electrochemical sensors. The optimized ink comprises graphite, carbon black, and nail polish, respectively (35.3:11.7:53%), as well as acetone as a solvent. The proportion was optimized with consideration of the binder’s solubilization, the ink’s suitability for the screen-printing process, and lower electrical resistance. The materials used, and the resulting ink, were analyzed by way of Fourier transform infrared spectroscopy (FT-IR), scanning electron microscopy (SEM), Raman spectroscopy, electrochemical impedance spectroscopy (EIS), and cyclic voltammetry (CV). The charge transfer resistance (Rct) obtained was 0.348 kΩ. The conductive ink was used to print an electrode on a PET substrate, and a flexible and disposable electrode was obtained. The electroactive area obtained was 13.7 cm2, which was calculated by the Randles-Sevcik equation. The applicability of the device was demonstrated with a redox probe, providing a sensitivity of 0.02 µ A L mmol−1. The conductive ink has adequate homogeneity for producing electrodes using the screen-printing technique, with a low estimated production cost of $ 0.09 mL−1.

Published

2023

3. Characterization of Silver Conductive Ink Screen-Printed Textile Circuits: Effects of Substrate, Mesh Density, and Overprinting

Author

Hyobin Im and Jung-Sim Roh

Subjects

screen printing, electronic textiles, textile circuits, conductive ink, smart wearables, screen-printing processes, Technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Engineering (General). Civil engineering (General), TA1-2040, Microscopy, QH201-278.5, Descriptive and experimental mechanics, QC120-168.85

Abstract

This study explores the intricate interaction between the properties of textile substrates and screen-printing parameters in shaping fabric circuits using silver conductive ink. Via analyzing key variables such as fabric type, mesh density, and the number of overprinted layers, the research revealed how the porous structure, large surface area, and fiber morphology of textile substrates influence ink absorption, ultimately enhancing the electrical connectivity of the printed circuits. Notably, the hydrophilic cotton staple fibers fabric effectively absorbed the conductive ink into the fabric substrate, demonstrating superior electrical performance compared with the hydrophobic polyester filament fabric after three overprinting, unlike the results observed after a single print. As mesh density decreased and the number of prints increased, the electrical resistance of the circuit gradually reduced, but ink bleeding on the fabric surface became more pronounced. Cotton fabric, via absorbing the ink deeply, exhibited less surface bleeding, while polyester fabric showed more noticeable ink spreading. These findings provide valuable insights for improving screen printing technology for textile circuits and contribute to the development of advanced fabric circuits that enhance the functionality of smart wearable technology.

Published

2024

4. Integrating High-Performance Flexible Wires with Strain Sensors for Wearable Human Motion Detection

Author

Pucheng Wu and Hu He

Subjects

flexible electronics, liquid metal, conductive ink, sintering process, mechanical stability, Chemical technology, TP1-1185

Abstract

Flexible electronics have revolutionized the field by overcoming the rigid limitations of traditional devices, offering superior flexibility and adaptability. Conductive ink performance is crucial, directly impacting the stability of flexible electronics. While metal filler-based inks exhibit excellent conductivity, they often lack mechanical stability. To address this challenge, we present a novel conductive ink utilizing a ternary composite filler system: liquid metal and two micron-sized silver morphologies (particles and flakes). We systematically investigated the influence of filler type, mass ratio, and sintering process parameters on the composite ink’s conductivity and mechanical stability. Our results demonstrate that flexible wires fabricated with the liquid metal/micron silver particle/micron silver flake composite filler exhibit remarkable conductivity and exceptional bending stability. Interestingly, increasing the liquid metal content results in a trade-off, compromising conductivity while enhancing mechanical performance. After enduring 5000 bending cycles, the resistance change in wires formulated with a 4:1 mass ratio of micron silver particles to flakes is only half that of wires with a 1:1 ratio. This study further investigates the mechanism governing resistance variations during flexible wire bending. Additionally, we observed a positive correlation between sintering temperature and pressure with the conductivity of flexible wires. The significance of the sintering parameters on conductivity follows a descending order: sintering temperature, sintering pressure, and sintering time. Finally, we demonstrate the practical application of this technology by integrating the composite ink-based flexible wires with conductive polymer-based strain sensors. This combination successfully achieved the detection of human movements, including finger and wrist bending.

Published

2024

5. The Synthesis of Copper Nanoparticles for Printed Electronic Materials Using Liquid Phase Reduction Method

Author

Kai Li and Xue Jiang

Subjects

printed electronics, copper nanoparticles, sintering, conductive ink, ascorbic acid reduction method, Technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Engineering (General). Civil engineering (General), TA1-2040, Microscopy, QH201-278.5, Descriptive and experimental mechanics, QC120-168.85

Abstract

This text discusses the synthesis of copper nanoparticles via a liquid phase reduction method, using ascorbic acid as a reducing agent and CuSO4·5H2O as the copper source. The synthesized copper nanoparticles are small in size, uniformly distributed, are mostly between 100–200 nm with clear boundaries between particles, and exhibit excellent dispersibility, making them suitable for metal conductive inks. 1. The copper nanoparticles are analyzed for good antioxidation properties, because their surface is coated with PVP and ascorbic acid. This organic layer somewhat isolates the particle surface from contact with air, preventing oxidation, and accounts for about 9% of the total weight. 2. When the prepared copper nanoparticles are spread on a polyimide substrate and sintered at 250 °C for 120 min, the resistivity can be as low as 23.5 μΩ·cm, and at 350 °C for 30 min, the resistivity is only three times that of bulk copper. 3. The prepared conductive ink, printed on a polyimide substrate using a direct writing tool, shows good flexibility before and after sintering. After sintering at 300 °C for 30 min and connecting the pattern to a circuit with a diode lamp, the diode lamp is successfully lit. 4. This method produces copper nanoparticles with small size, good dispersion, and antioxidation capabilities, and the conductive ink prepared from them demonstrates good conductivity after sintering.

Published

2024

6. Polydopamine/SWCNT Ink Functionalization of Silk Fabric to Obtain Electroconductivity at a Low Percolation Threshold

Author

Anna Baranowska-Korczyc, Dorota Kowalczyk, and Małgorzata Cieślak

Subjects

silk, silk fabric, SWCNT, conductive ink, conductivity, PDA, Biology (General), QH301-705.5, Chemistry, QD1-999

Abstract

This study presents the functionalization of silk fabric with SWCNT ink. The first step was the formation of a polydopamine (PDA) thin coating on the silk fabric to allow for effective bonding of SWCNTs. PDA formation was carried out directly on the fabric by means of polymerization of dopamine in alkali conditions. The Silk/PDA fabric was functionalized with SWCNT ink of different SWCNT concentrations by using the dip-coating method. IR and Raman analyses show that the dominant β-sheet structure of silk fibroin after the functionalization process remains unchanged. The heat resistance is even slightly improved. The hydrophobic silk fabric becomes hydrophilic after functionalization due to the influence of PDA and the surfactant in SWCNT ink. The ink significantly changes the electrical properties of the silk fabric, from insulating to conductive. The volume resistance changes by nine orders of magnitude, from 2.4 × 1012 Ω to 2.3 × 103 Ω for 0.12 wt.% of SWCNTs. The surface resistance changes by seven orders of magnitude, from 2.1 × 1012 Ω to 2.4 × 105 Ω for 0.17 wt.% of SWCNTs. The volume and surface resistance thresholds are determined to be about 0.05 wt.% and 0.06 wt.%, respectively. The low value of the percolation threshold indicates efficient functionalization, with high-quality ink facilitating the formation of percolation paths through SWCNTs and the influence of the PDA linker.

Published

2024

7. Crack Detecting Method Based on Grid-Type Sensing Networks Using Electrical Signals

Author

Ju-Hun Ahn, Yong-Chan Lee, Se-Min Jeong, Han-Na Kim, and Chang-Yull Lee

Subjects

electrohydrodynamics, crack detecting, micro-crack sensor, conductive ink, Chemical technology, TP1-1185

Abstract

Cracks have a primary effect on the failure of a structure. Therefore, the development of crack sensors with high accuracy and resolution and cracks detection method are important. In this study, the crack sensors were fabricated, and the crack locations were detected with the electrical signal of the crack sensor. First, a metal grid-type micro-crack sensor based on silver was fabricated. The sensor is made with electrohydrodynamics (EHD) inkjet printing technology, which is well known as the next generation of printed electronics technology. Optimal printing conditions were established through experiments, and a grid sensor was obtained. After that, single cracks and multiple cracks were simulated on the sensor, and electrical signals generated from the sensor were measured. The measured electrical signal tracked the location of the cracks in three steps: simple cross-calculation, interpolation, and modified P-SPICE. It was confirmed that cracks could be effectively found and displayed using the method presented in this paper.

Published

2023

8. Facile Preparation of Monodisperse Cu@Ag Core–Shell Nanoparticles for Conductive Ink in Printing Electronics

Author

Gang Li, Xuecheng Yu, Ruoyu Zhang, Qionglin Ouyang, Rong Sun, Liqiang Cao, and Pengli Zhu

Subjects

core–shell nanoparticles, antioxidation, conductive ink, printing electronics, Mechanical engineering and machinery, TJ1-1570

Abstract

Copper-based nanoinks are emerging as promising low-cost alternatives to widely used silver nanoinks in electronic printing. However, the spontaneous oxidation of copper under ambient conditions poses significant challenges to its broader application. To address this issue, this paper presents an economical, large-scale, and environmentally friendly method for fabricating Cu@Ag nanoparticles (Cu@Ag NPs). The as-prepared nanoparticles exhibit a narrow size distribution of approximately 100 nm and can withstand ambient exposure for at least 60 days without significant oxidation. The Cu@Ag-based ink, with a 60 wt% loading, was screen-printed onto a flexible polyimide substrate and subsequently heat-treated at 290 °C for 15 minutes under a nitrogen atmosphere. The sintered pattern displayed a low electrical resistivity of 25.5 μΩ·cm (approximately 15 times the resistivity of bulk copper) along with excellent reliability and mechanical fatigue strength. The innovative Cu@Ag NPs fabrication method holds considerable potential for advancing large-scale applications of copper-based inks in flexible electronics.

Published

2023

9. Conductivity Enhancement of Graphene and Graphene Derivatives by Silver Nanoparticles

Author

Apostolos Koutsioukis, Katerina Vrettos, Vassiliki Belessi, and Vasilios Georgakilas

Subjects

conductive ink, graphene hybrid, gravure printing, silver nanoparticles, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

In this article, a facile way for the doping of graphene and graphene derivatives with silver nanoparticles at different Ag ratios is described. Ag nanoparticles were formed directly on the surface of two different graphene substrates dispersed in dimethylformamide by the reduction of Ag cations with NaBH4. A few layered graphene nanosheets (FLG) produced from graphite and reduced graphene oxide functionalized with amino arylsulfonates (f-rGO) were used as substrates. The final graphene/Ag nanoparticle hybrid in the form of solid, dense spots showed enhanced electrical conductivity, which can be attributed to the formation of conductive interconnections between the 2D nanosheets. Importantly, electrical conductivities of 20 and 167 103 S m−1 were measured for the hybrids of f-rGO and FLG, respectively, with the higher Ag percentage without an annealing process. A representative hybrid f-rGO with Ag nanoparticles was used for the development of a highly conductive water-based gravure ink with excellent printing properties.

Published

2023

10. A Review on Sustainable Inks for Printed Electronics: Materials for Conductive, Dielectric and Piezoelectric Sustainable Inks

Author

Leire Sanchez-Duenas, Estibaliz Gomez, Mikel Larrañaga, Miren Blanco, Amaia M. Goitandia, Estibaliz Aranzabe, and José Luis Vilas-Vilela

Subjects

printed electronics, sustainable materials for printed electronic inks, conductive ink, dielectric ink, piezoelectric ink, biobased ink, Technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Engineering (General). Civil engineering (General), TA1-2040, Microscopy, QH201-278.5, Descriptive and experimental mechanics, QC120-168.85

Abstract

In the last decades, the demand for electronics and, therefore, electronic waste, has increased. To reduce this electronic waste and the impact of this sector on the environment, it is necessary to develop biodegradable systems using naturally produced materials with low impact on the environment or systems that can degrade in a certain period. One way to manufacture these types of systems is by using printed electronics because the inks and the substrates used are sustainable. Printed electronics involve different methods of deposition, such as screen printing or inkjet printing. Depending on the method of deposition selected, the developed inks should have different properties, such as viscosity or solid content. To produce sustainable inks, it is necessary to ensure that most of the materials used in the formulation are biobased, biodegradable, or not considered critical raw materials. In this review, different inks for inkjet printing or screen printing that are considered sustainable, and the materials that can be used to formulate them, are collected. Printed electronics need inks with different functionalities, which can be mainly classified into three groups: conductive, dielectric, or piezoelectric inks. Materials need to be selected depending on the ink’s final purpose. For example, functional materials such as carbon or biobased silver should be used to secure the conductivity of an ink, a material with dielectric properties could be used to develop a dielectric ink, or materials that present piezoelectric properties could be mixed with different binders to develop a piezoelectric ink. A good combination of all the components selected must be achieved to ensure the proper features of each ink.

Published

2023

11. Conductive Ink-Coated Paper-Based Supersandwich DNA Biosensor for Ultrasensitive Detection of Neisseria gonorrhoeae

Author

Niharika Gupta, D. Kumar, Asmita Das, Seema Sood, and Bansi D. Malhotra

Subjects

DNA biosensor, Neisseria gonorrhoeae, conductive ink, electrochemical, infectious diseases, Biotechnology, TP248.13-248.65

Abstract

Herein, we report results of the studies relating to the development of an impedimetric, magnetic bead-assisted supersandwich DNA hybridization assay for ultrasensitive detection of Neisseria gonorrhoeae, the causative agent of a sexually transmitted infection (STI), gonorrhea. First, a conductive ink was formulated by homogenously dispersing carboxylated multiwalled carbon nanotubes (cMWCNTs) in a stable emulsion of terpineol and an aqueous suspension of carboxymethyl cellulose (CMC). The ink, labeled C5, was coated onto paper substrates to fabricate C5@paper conductive electrodes. Thereafter, a magnetic bead (MB)-assisted supersandwich DNA hybridization assay was optimized against the porA pseudogene of N. gonorrhoeae. For this purpose, a pair of specific 5′ aminated capture probes (SCP) and supersandwich detector probes (SDP) was designed, which allowed the enrichment of target gonorrheal DNA sequence from a milieu of substances. The SD probe was designed such that instead of 1:1 binding, it allowed the binding of more than one T strand, leading to a ‘ladder-like’ DNA supersandwich structure. The MB-assisted supersandwich assay was integrated into the C5@paper electrodes for electrochemical analysis. The C5@paper electrodes were found to be highly conductive by a four-probe conductivity method (maximum conductivity of 10.1 S·cm−1). Further, the biosensing assay displayed a wide linear range of 100 aM-100 nM (109 orders of magnitude) with an excellent sensitivity of 22.6 kΩ·(log[concentration])−1. The clinical applicability of the biosensing assay was assessed by detecting genomic DNA extracted from N. gonorrhoeae in the presence of DNA from different non-gonorrheal bacterial species. In conclusion, this study demonstrates a highly sensitive, cost-effective, and label-free paper-based device for STI diagnostics. The ink formulation prepared for the study was found to be highly thixotropic, which indicates that the paper electrodes can be screen-printed in a reproducible and scalable manner.

Published

2023

12. Amphiphilic Silver Nanoparticles for Inkjet-Printable Conductive Inks

Author

Irena Ivanišević, Marin Kovačić, Marko Zubak, Antonia Ressler, Sara Krivačić, Zvonimir Katančić, Iva Gudan Pavlović, and Petar Kassal

Subjects

silver nanoparticles, amphiphilic particles, density functional theory, conductive ink, inkjet printing, flexible electronics, Chemistry, QD1-999

Abstract

The large-scale manufacturing of flexible electronics is nowadays based on inkjet printing technology using specially formulated conductive inks, but achieving adequate wetting of different surfaces remains a challenge. In this work, the development of a silver nanoparticle-based functional ink for printing on flexible paper and plastic substrates is demonstrated. Amphiphilic silver nanoparticles with narrow particle size distribution and good dispersibility were prepared via a two-step wet chemical synthesis procedure. First, silver nanoparticles capped with poly(acrylic acid) were prepared, followed by an amidation reaction with 3-morpholynopropylamine (MPA) to increase their lipophilicity. Density functional theory (DFT) calculations were performed to study the interactions between the particles and the dispersion medium in detail. The amphiphilic nanoparticles were dispersed in solvents of different polarity and their physicochemical and rheological properties were determined. A stable ink containing 10 wt% amphiphilic silver nanoparticles was formulated and inkjet-printed on different surfaces, followed by intense pulsed light (IPL) sintering. Low sheet resistances of 3.85 Ω sq–1, 0.57 Ω sq–1 and 19.7 Ω sq–1 were obtained for the paper, coated poly(ethylene terephthalate) (PET) and uncoated polyimide (PI) flexible substrates, respectively. Application of the nanoparticle ink for printed electronics was demonstrated via a simple flexible LED circuit.

Published

2022

13. Nano Porous Zinc Synthesis on Soft Polyurethane Foam Using Conductive Ink and Electroplating Method

Author

Mehdi Salimi, Seyed Mohammad Mousavi Khoiee, Eskandar Keshavarz Alamdari, Milad Rezaei, and Maryam Karbasi

Subjects

zinc nanoparticle, nano pores, conductive ink, zinc foam, specific surface area, Mining engineering. Metallurgy, TN1-997

Abstract

High specific surface is a significant characteristic in zinc coatings that can be highly applicable in batteries and catalysts. Conventional methods to create foams are not cost-efficient, nor could they make a high specific surface. Electroplating has been developed that can produce a very high specific surface foam. On the other hand, conductive ink can create an affordable conductive surface with a high specific surface, so the study on using conductive ink, which has a cost-efficient nature, was necessary to create a conductive surface. This work has investigated the effect of crucial parameters, such as graphite size, coating time and bath composition, on the current efficiency and SEM microstructure. As a result, a 3 µm graphite size was found to be appropriate. Coated zinc escalates linearly with current efficiency for up to 5 h, and then it decreases. Although the zinc concentration increases up to 0.12 mol/L in the electrolyte, making a slight increase in loading, the current efficiency was almost unchanged. However, if it increases more, the loading and current efficiency significantly rise so that the loading grows up to 16 times and the current density increases up to 86%. Additionally, the morphology changes from dendritic to compact plates, sphere and semi-sphere, subsequently.

Published

2022

14. Conductive Inks Based on Melamine Intercalated Graphene Nanosheets for Inkjet Printed Flexible Electronics

Author

Magdalena Kralj, Sara Krivačić, Irena Ivanišević, Marko Zubak, Antonio Supina, Marijan Marciuš, Ivan Halasz, and Petar Kassal

Subjects

mechanochemistry, graphene nanosheets, conductive ink, inkjet printing, printed electronics, Chemistry, QD1-999

Abstract

With the growing number of flexible electronics applications, environmentally benign ways of mass-producing graphene electronics are sought. In this study, we present a scalable mechanochemical route for the exfoliation of graphite in a planetary ball mill with melamine to form melamine-intercalated graphene nanosheets (M-GNS). M-GNS morphology was evaluated, revealing small particles, down to 14 nm in diameter and 0.4 nm thick. The M-GNS were used as a functional material in the formulation of an inkjet-printable conductive ink, based on green solvents: water, ethanol, and ethylene glycol. The ink satisfied restrictions regarding stability and nanoparticle size; in addition, it was successfully inkjet printed on plastic sheets. Thermal and photonic post-print processing were evaluated as a means of reducing the electrical resistance of the printed features. Minimal sheet resistance values (5 kΩ/sq for 10 printed layers and 626 Ω/sq for 20 printed layers) were obtained on polyimide sheets, after thermal annealing for 1 h at 400 °C and a subsequent single intense pulsed light flash. Lastly, a proof-of-concept simple flexible printed circuit consisting of a battery-powered LED was realized. The demonstrated approach presents an environmentally friendly alternative to mass-producing graphene-based printed flexible electronics.

Published

2022

15. Facile Synthesis of Silver Nanoparticles and Preparation of Conductive Ink

Author

Gui Bing Hong, Yi Hua Luo, Kai Jen Chuang, Hsiu Yueh Cheng, Kai Chau Chang, and Chih Ming Ma

Subjects

silver nanoparticles, conductive ink, chemical reduction, electrical resistivity, Chemistry, QD1-999

Abstract

In the scientific industry, sustainable nanotechnology has attracted great attention and has been successful in facilitating solutions to challenges presented in various fields. For the present work, silver nanoparticles (AgNPs) were prepared using a chemical reduction synthesis method. Then, a low-temperature sintering process was deployed to obtain an Ag-conductive ink preparation which could be applied to a flexible substrate. The size and shape of the AgNPs were characterized by ultraviolet–visible spectrophotometry (UV-Vis) and transmission electron microscopy (TEM). The experiments indicated that the size and agglomeration of the AgNPs could be well controlled by varying the reaction time, reaction temperature, and pH value. The rate of nanoparticle generation was the highest when the reaction temperature was 100 °C within the 40 min reaction time, achieving the most satisfactorily dispersed nanoparticles and nanoballs with an average size of 60.25 nm at a pH value of 8. Moreover, the electrical resistivity of the obtained Ag-conductive ink is controllable, under the optimal sintering temperature and time (85 °C for 5 min), leading to an optimal electrical resistivity of 9.9 × 10−6 Ω cm. The results obtained in this study, considering AgNPs and Ag-conductive ink, may also be extended to other metals in future research.

Published

2022

16. Direct Laser Interference Ink Printing Using Copper Metal–Organic Decomposition Ink for Nanofabrication

Author

Jun-Han Park, Jung-Woon Lee, Yong-Won Ma, Bo-Seok Kang, Sung-Moo Hong, and Bo-Sung Shin

Subjects

laser printing, laser interference, direct energy deposition, metal printing, conductive ink, Chemistry, QD1-999

Abstract

In this study, we developed an effective and rapid process for nanoscale ink printing, direct laser interference ink printing (DLIIP), which involves the photothermal reaction of a copper-based metal–organic decomposition ink. A periodically lined copper pattern with a width of 500 nm was printed on a 240 μm-wide line at a fabrication speed of 17 mm/s under an ambient environment and without any pre- or post-processing steps. This pattern had a resistivity of 3.5 μΩ∙cm, and it was found to exhibit a low oxidation state that was twice as high as that of bulk copper. These results demonstrate the feasibility of DLIIP for nanoscale copper printing with fine electrical characteristics.

Published

2022

17. Innovative Eco-Friendly Conductive Ink Based on Carbonized Lignin for the Production of Flexible and Stretchable Bio-Sensors

Author

Daniele Zappi, Gabriele Varani, Enrico Cozzoni, Igor Iatsunskyi, Serena Laschi, and Maria Teresa Giardi

Subjects

waste recycling, carbonized lignin, conductive ink, screen-printed electrodes, flexible stretchable bio-sensor, Chemistry, QD1-999

Abstract

In this study, we report a novel way to produce carbon-based conductive inks for electronic and sensor technology applications. Carbonized lignin, obtained from the waste products of the Eucalyptus globulus tree paper industry, was used to produce a stable conductive ink. To this end, liquid-phase compositions were tested with different amounts of carbonized lignin powder to obtain an ink with optimal conductivity and rheological properties for different possible uses. The combination that showed the best properties, both regarding electrochemical properties and green compatibility of the materials employed, was cyclohexanone/cellulose acetate/carbonized lignin 5% (w/w), which was used to produce screen-printed electrodes. The electrodes were characterized from a structural and electrochemical point of view, resulting in an electrochemically active area of 0.1813 cm2, compared to the electrochemically active area of 0.1420 cm2 obtained by employing geometrically similar petroleum-based screen-printed electrodes and, finally, their performance was demonstrated for the quantification of uric acid, with a limit of detection of 0.3 μM, and their biocompatibility was assessed by testing it with the laccase enzyme and achieving a limit of detection of 2.01 μM for catechol as the substrate. The results suggest that the developed ink could be of great use in both sensor and electronic industries, reducing the overall ecological impact of traditionally used petroleum-based inks.

Published

2021

18. Inkjet Printing of Flexible Transparent Conductive Films with Silver Nanowires Ink

Author

Xiaoli Wu, Shuyue Wang, Zhengwu Luo, Jiaxin Lu, Kaiwen Lin, Hui Xie, Yuehui Wang, and Jing-Ze Li

Subjects

silver nanowires, conductive ink, inkjet printing, flexible transparent conductive films, photoelectric property, Chemistry, QD1-999

Abstract

The inkjet printing process is a promising electronic printing technique for large-scale, printed, flexible and stretchable electronics because of features such as its high manufacturing speed, environmental friendliness, simple process, low cost, accurate positioning, and so on. As the base material of printed conductive patterns, conductive ink is the foundation of the development of printed electronics technology, and directly affects the performance and the quality of electronic products. In this paper, conductive ink with silver nanowires (AgNWs) was prepared, with AgNWs of lengths of 2–5 µm and diameters of 20 nm or so, isopropyl alcohol and ethylene glycol as the mixed solvents, and modified polysilane as the wetting agent. We discussed the relationship between the formula of the AgNWs ink and the surface tension, viscosity, contact angle between ink droplet and poly(ethylene) terephthalate (PET) surface, as well as the film-forming properties of the ink. Further, we analyzed the effects of the number of printed layers and the ink concentration of the AgNWs on the microstructures, photoelectric properties and accuracy of the printed patterns, as well as the change in the sheet resistance of the film during different bending cycles. The experimental results show that flexible transparent conductive patterns with a light transmittance of 550 nm of 83.1–88.4% and a sheet resistance of 34.0 Ω∙sq−1–78.3 nm∙sq−1 can be obtained by using AgNWs ink of 0.38 mg∙mL−1 to 0.57 mg∙mL−1, a poly (ethylene terephthalate) (PET) substrate temperature of 40 °C, a nozzle temperature of 35 °C, and heat treated at 60 °C for 10 min. These performances indicate the excellent potential of the inkjet printing of AgNWs networks for developing flexible transparent conductive film.

Published

2021

19. Interconnections for Additively Manufactured Hybridized Printed Electronics in Harsh Environments

Author

Clayton Neff, Edwin Elston, and Amanda Schrand

Subjects

conductive epoxy, conductive ink, harsh environments, high acceleration testing, interconnections, low temperature solder, Technology, Engineering design, TA174

Abstract

The ability to fabricate functional 3D conductive elements via additive manufacturing has opened up a unique sector of ‘hybridized printed electronics’. In doing so, many of the rigid standards (i.e., planar circuit boards, potting, etc.,) of traditional electronics are abandoned. However, one critical challenge lies in producing robust and reliable interconnections between conductive inks and traditional hardware, especially when subjected to harsh environments. This research examines select material pairings for the most resilient interconnection. The method of test is wire bond pull testing that would represent a continuous strain on a connection and high acceleration testing of up to 50,000 g that would represent a sudden shock that electronics may experience in a drop or crash. Although these two environments may be similar to an overall energy exerted on the connection, the rate of force exerted may lead to different solutions. The results of this research provide insight into material selection for printed electronic interconnections and a framework for interconnection resiliency assessment, which is a critical aspect in realizing the production of next generation electronics technologies for the most demanding environments.

Published

2020

20. High-Yield Production of Aqueous Graphene for Electrohydrodynamic Drop-on-Demand Printing of Biocompatible Conductive Patterns

Author

Amir Ehsan Niaraki Asli, Jingshuai Guo, Pei Lun Lai, Reza Montazami, and Nicole N. Hashemi

Subjects

graphene, inkjet printing, conductive ink, flexible electronics, neuronal sensing, Biotechnology, TP248.13-248.65

Abstract

Presented here is a scalable and aqueous phase exfoliation of graphite to high yield and quality of few layer graphene (FLG) using Bovine Serum Albomine (BSA) and wet ball milling. The produced graphene ink is tailored for printable and flexible electronics, having shown promising results in terms of electrical conductivity and temporal stability. Shear force generated by steel balls which resulted in 2−3 layer defect-free graphene platelets with an average size of hundreds of nm, and with a concentration of about 5.1 mg/mL characterized by Raman spectroscopy, atomic force microscopy (AFM), transmittance electron microscopy (TEM) and UV-vis spectroscopy. Further, a conductive ink was prepared and printed on flexible substrate (Polyimide) with controlled resolution. Scanning electron microscopy (SEM) and Profilometry revealed the effect of thermal annealing on the prints to concede consistent morphological characteristics. The resulted sheet resistance was measured to be R s = 36.75 Ω / sqr for prints as long as 100 mm. Printable inks were produced in volumes ranging from 20 mL to 1 L, with potential to facilitate large scale production of graphene for applications in biosensors, as well as flexible and printable electronics.

Published

2020

21. A Smart Shirt Made with Conductive Ink and Conductive Foam for the Measurement of Electrocardiogram Signals with Unipolar Precordial Leads

Author

Yasunori Tada, Yusaku Amano, Tomonobu Sato, Shigeru Saito, and Masahiro Inoue

Subjects

smart shirt, conductive ink, conductive foam, electrocardiogram measurement, Chemicals: Manufacture, use, etc., TP200-248, Textile bleaching, dyeing, printing, etc., TP890-933, Biology (General), QH301-705.5, Physics, QC1-999

Abstract

The Holter monitor is used to measure an electrocardiogram (ECG) signal while a subject moves. However, the Holter monitor is uncomfortable for the subject. Another method of measuring the ECG signal uses a smart shirt. We developed a smart shirt that has six electrodes on the chest and can measure a detailed ECG, obtained with unipolar precordial leads. The electrodes and wires of the shirt are made of conductive ink that is flexible and stretchable. The smart shirt is stretchable and fits the body well. However, because of the gap between the smart shirt and the body, electrodes V1 and V2 do not touch the body consistently. We developed a conductive foam block that fills this gap. We investigated the characteristics of the conductive foam block, and measured ECG signals using the smart shirt. The electrical resistance of the conductive foam block was reduced by pressure. This characteristic could be utilized to measure the ECG signal because the block was pressed by the body and smart shirt. We could measure the ECG signal using the smart shirt and blocks while the subject walked and could detect peaks of the ECG signal while the subject jogged slowly.

Published

2015

22. Microstructural and Process Characterization of Conductive Traces Printed from Ag Particulate Inks

Author

Eric MacDonald, Ken Church, Lawrence E. Murr, Ryan B. Wicker, and David A. Roberson

Subjects

conductive ink, Ag nanoparticles, inkjet, scanning electron microscopy, microstructures, Technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Engineering (General). Civil engineering (General), TA1-2040, Microscopy, QH201-278.5, Descriptive and experimental mechanics, QC120-168.85

Abstract

Conductive inks are key enablers for the use of printing techniques in the fabrication of electronic systems. Focus on the understanding of aspects controlling the electrical performance of conductive ink is paramount. A comparison was made between microparticle Ag inks and an Ag nanoparticle ink. The microstructures resulting from thermal cure processes were characterized morphologically and also in terms of their effect on the resistivity of printed traces. For microparticle inks, the variability of resistivity measurements between samples as defined by coefficient of variation (CV) was greater than 0.1 when the resistivity was 10 to 50 times that of bulk Ag. When the resistivity was lower (~1.4 times that of bulk Ag) the CV of sample sets was less than 0.1. In the case of the nanoparticle ink, resistivity was found to decrease by a factor ranging from 1.2 to 1.5 after doubling the amount of layers printed prior to curing though it was expected to remain the same. Increasing the amount of layers printed also enhanced the sintering process.

Published

2011

23. Design of A Low-Cost and Disposable Paper-Based Immunosensor for the Rapid and Sensitive Detection of Aflatoxin B1

Author

Andrey Soares, Osvaldo N. Oliveira, Fernanda L. Migliorini, Daniel S. Correa, Luiz H. C. Mattoso, and Danilo Martins dos Santos

Subjects

Aflatoxin, Working electrode, Materials science, POLÍMEROS (MATERIAIS), 02 engineering and technology, Carbon nanotube, 01 natural sciences, paper-based sensor, disposable immunosensor, Analytical Chemistry, law.invention, Chitosan, lcsh:Biochemistry, chemistry.chemical_compound, law, Conductive ink, lcsh:QD415-436, Physical and Theoretical Chemistry, Detection limit, Chromatography, carbon nanotubes, 010401 analytical chemistry, Substrate (chemistry), 021001 nanoscience & nanotechnology, 0104 chemical sciences, Dielectric spectroscopy, chemistry, electrochemical detection, aflatoxin B1, chitosan, 0210 nano-technology

Abstract

We report a paper-based electrochemical immunosensor made with sustainable materials to detect aflatoxin B1 (AFB1), a highly toxic, carcinogenic mycotoxin found in food. The immunosensor was prepared with a waterproof paper substrate and low-cost graphite-based conductive ink through a simple cut-printing method. The working electrode was functionalized with a drop-cast film of multiwalled carbon nanotubes (MWCNT)/chitosan on which a layer of anti-AFB1 monoclonal antibodies was immobilized covalently. The architecture of the immunosensor was confirmed with polarization-modulated infrared reflection absorption spectroscopy (PM-IRRAS) and electrochemical impedance spectroscopy (EIS), including the effective immobilization of the active layer of anti-AFB1. With EIS as the principle of detection, the immunosensor could detect AFB1 in the range from 1 to 30 ng&middot, mL&minus, 1, and detection limit of 0.62 ng&middot, 1. This sensitivity is sufficient to detect AFB1 in food according to regulatory agencies. The immunosensor exhibited good repeatability, reproducibility, stability, and selectivity in experiments with a possible interferent. Furthermore, detection of AFB1 in maize flour samples yielded recovery of 97&ndash, 99%, in a demonstration of the possible use of the paper-based immunosensor to detect AFB1 using extraction solutions from food samples.

Published

2020

24. Interconnections for Additively Manufactured Hybridized Printed Electronics in Harsh Environments

Author

Edwin Elston, Clayton Neff, and Amanda M. Schrand

Subjects

Wire bonding, conductive epoxy, conductive ink, harsh environments, high acceleration testing, interconnections, low temperature solder, printed electronics, wire bond pull testing, Computer science, 02 engineering and technology, 01 natural sciences, lcsh:Technology, Industrial and Manufacturing Engineering, Printed circuit board, Material selection, lcsh:TA174, 0103 physical sciences, Conductive ink, Electronics, Engineering (miscellaneous), 010302 applied physics, Interconnection, business.industry, lcsh:T, Mechanical Engineering, Electrical engineering, 021001 nanoscience & nanotechnology, lcsh:Engineering design, Potting, Printed electronics, 0210 nano-technology, business

Abstract

The ability to fabricate functional 3D conductive elements via additive manufacturing has opened up a unique sector of ‘hybridized printed electronics’. In doing so, many of the rigid standards (i.e., planar circuit boards, potting, etc.,) of traditional electronics are abandoned. However, one critical challenge lies in producing robust and reliable interconnections between conductive inks and traditional hardware, especially when subjected to harsh environments. This research examines select material pairings for the most resilient interconnection. The method of test is wire bond pull testing that would represent a continuous strain on a connection and high acceleration testing of up to 50,000 g that would represent a sudden shock that electronics may experience in a drop or crash. Although these two environments may be similar to an overall energy exerted on the connection, the rate of force exerted may lead to different solutions. The results of this research provide insight into material selection for printed electronic interconnections and a framework for interconnection resiliency assessment, which is a critical aspect in realizing the production of next generation electronics technologies for the most demanding environments.

Published

2020

25. Comparison of E-Textile Techniques and Materials for 3D Gesture Sensor with Boosted Electrode Design

Author

Raúl Llinares Llopis, José Vicente Lidon Roger, Eduardo Garcia-Breijo, Gabriel Martinez, and Josue Ferri

Subjects

Textile, touchless, Computer science, E-textile techniques, Wearable computer, 02 engineering and technology, Biosensing Techniques, lcsh:Chemical technology, 01 natural sciences, Biochemistry, Automotive engineering, Article, Analytical Chemistry, Gesture recognition, Touchless, TECNOLOGIA ELECTRONICA, Wearable Electronic Devices, Conductive ink, TEORIA DE LA SEÑAL Y COMUNICACIONES, Humans, lcsh:TP1-1185, Electrical and Electronic Engineering, Instrumentation, Electrodes, E-field sensors, Gestures, business.industry, Wearables, gesture recognition, 010401 analytical chemistry, e-textile techniques, 021001 nanoscience & nanotechnology, Atomic and Molecular Physics, and Optics, 0104 chemical sciences, e-field sensors, wearables, 0210 nano-technology, business, Gesture

Abstract

[EN] There is an interest in new wearable solutions that can be directly worn on the curved human body or integrated into daily objects. Textiles offer properties that are suitable to be used as holders for electronics or sensors components. Many sensing technologies have been explored considering textiles substrates in combination with conductive materials in the last years. In this work, a novel solution of a gesture recognition touchless sensor is implemented with satisfactory results. Moreover, three manufacturing techniques have been considered as alternatives: screen-printing with conductive ink, embroidery with conductive thread and thermosealing with conductive fabric. The main critical parameters have been analyzed for each prototype including the sensitivity of the sensor, which is an important and specific parameter of this type of sensor. In addition, user validation has been performed, testing several gestures with different subjects. During the tests carried out, flick gestures obtained detection rates from 79% to 89% on average. Finally, in order to evaluate the stability and strength of the solutions, some tests have been performed to assess environmental variations and washability deteriorations. The obtained results are satisfactory regarding temperature and humidity variations. The washability tests revealed that, except for the screen-printing prototype, the sensors can be washed with minimum degradation., This work was supported by the Spanish Government/FEDER funds (RTI2018-100910-B-C43) (MINECO/FEDER). The work presented is also funded by the Conselleria d'Economia Sostenible, Sectors Productius i Treball, through IVACE (Instituto Valenciano de Competitividad Empresarial) and cofounded by ERDF funding from the EU. Application No.: IMAMCI/2020/1

Published

2020

26. Amphiphilic Silver Nanoparticles for Inkjet-Printable Conductive Inks.

Author

Ivanišević I, Kovačić M, Zubak M, Ressler A, Krivačić S, Katančić Z, Gudan Pavlović I, and Kassal P

Abstract

The large-scale manufacturing of flexible electronics is nowadays based on inkjet printing technology using specially formulated conductive inks, but achieving adequate wetting of different surfaces remains a challenge. In this work, the development of a silver nanoparticle-based functional ink for printing on flexible paper and plastic substrates is demonstrated. Amphiphilic silver nanoparticles with narrow particle size distribution and good dispersibility were prepared via a two-step wet chemical synthesis procedure. First, silver nanoparticles capped with poly(acrylic acid) were prepared, followed by an amidation reaction with 3-morpholynopropylamine (MPA) to increase their lipophilicity. Density functional theory (DFT) calculations were performed to study the interactions between the particles and the dispersion medium in detail. The amphiphilic nanoparticles were dispersed in solvents of different polarity and their physicochemical and rheological properties were determined. A stable ink containing 10 wt% amphiphilic silver nanoparticles was formulated and inkjet-printed on different surfaces, followed by intense pulsed light (IPL) sintering. Low sheet resistances of 3.85 Ω sq -1 , 0.57 Ω sq -1 and 19.7 Ω sq -1 were obtained for the paper, coated poly(ethylene terephthalate) (PET) and uncoated polyimide (PI) flexible substrates, respectively. Application of the nanoparticle ink for printed electronics was demonstrated via a simple flexible LED circuit.

Published

2022

27. Conductive Inks Based on Melamine Intercalated Graphene Nanosheets for Inkjet Printed Flexible Electronics.

Author

Kralj M, Krivačić S, Ivanišević I, Zubak M, Supina A, Marciuš M, Halasz I, and Kassal P

Abstract

With the growing number of flexible electronics applications, environmentally benign ways of mass-producing graphene electronics are sought. In this study, we present a scalable mechanochemical route for the exfoliation of graphite in a planetary ball mill with melamine to form melamine-intercalated graphene nanosheets (M-GNS). M-GNS morphology was evaluated, revealing small particles, down to 14 nm in diameter and 0.4 nm thick. The M-GNS were used as a functional material in the formulation of an inkjet-printable conductive ink, based on green solvents: water, ethanol, and ethylene glycol. The ink satisfied restrictions regarding stability and nanoparticle size; in addition, it was successfully inkjet printed on plastic sheets. Thermal and photonic post-print processing were evaluated as a means of reducing the electrical resistance of the printed features. Minimal sheet resistance values (5 kΩ/sq for 10 printed layers and 626 Ω/sq for 20 printed layers) were obtained on polyimide sheets, after thermal annealing for 1 h at 400 °C and a subsequent single intense pulsed light flash. Lastly, a proof-of-concept simple flexible printed circuit consisting of a battery-powered LED was realized. The demonstrated approach presents an environmentally friendly alternative to mass-producing graphene-based printed flexible electronics.

Published

2022

28. Screen Printing Carbon Nanotubes Textiles Antennas for Smart Wearables

Author

Dilan Arslan, Amir Asadi, Akram Alomainy, Elif Ozden Yenigun, Isidoro Ibanez Labiano, and Hulya Cebeci

Subjects

E-textiles, Computer science, Conformal antenna, Wearable computer, Nanotechnology, TP1-1185, 02 engineering and technology, flexible printed antennas, 010402 general chemistry, 01 natural sciences, Biochemistry, Article, Analytical Chemistry, Wearable Electronic Devices, Conductive ink, Humans, Electronics, Electrical and Electronic Engineering, e-textiles, Instrumentation, Nanotubes, Carbon, Chemical technology, Textiles, Electric Conductivity, screen printing, 021001 nanoscience & nanotechnology, carbon nanotubes inks, Atomic and Molecular Physics, and Optics, 0104 chemical sciences, wearables, Screen printing, Antenna gain, Antenna (radio), 0210 nano-technology

Abstract

Electronic textiles have become a dynamic research field in recent decades, attracting attention to smart wearables to develop and integrate electronic devices onto clothing. Combining traditional screen-printing techniques with novel nanocarbon-based inks offers seamless integration of flexible and conformal antenna patterns onto fabric substrates with a minimum weight penalty and haptic disruption. In this study, two different fabric-based antenna designs called PICA and LOOP were fabricated through a scalable screen-printing process by tuning the conductive ink formulations accompanied by cellulose nanocrystals. The printing process was controlled and monitored by revealing the relationship between the textiles’ nature and conducting nano-ink. The fabric prototypes were tested in dynamic environments mimicking complex real-life situations, such as being in proximity to a human body, and being affected by wrinkling, bending, and fabric care such as washing or ironing. Both computational and experimental on-and-off-body antenna gain results acknowledged the potential of tunable material systems complimenting traditional printing techniques for smart sensing technology as a plausible pathway for future wearables.

Published

2021

29. Inkjet Printing of Flexible Transparent Conductive Films with Silver Nanowires Ink

Author

Jingze Li, Hui Xie, Yuehui Wang, Kaiwen Lin, Jiaxin Lu, Shuyue Wang, Xiaoli Wu, and Zhengwu Luo

Subjects

Materials science, photoelectric property, General Chemical Engineering, flexible transparent conductive films, Stretchable electronics, 02 engineering and technology, Substrate (printing), 010402 general chemistry, 01 natural sciences, Article, Contact angle, Conductive ink, General Materials Science, Composite material, QD1-999, Sheet resistance, inkjet printing, Inkwell, conductive ink, silver nanowires, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Chemistry, Printed electronics, Wetting, 0210 nano-technology

Abstract

The inkjet printing process is a promising electronic printing technique for large-scale, printed, flexible and stretchable electronics because of features such as its high manufacturing speed, environmental friendliness, simple process, low cost, accurate positioning, and so on. As the base material of printed conductive patterns, conductive ink is the foundation of the development of printed electronics technology, and directly affects the performance and the quality of electronic products. In this paper, conductive ink with silver nanowires (AgNWs) was prepared, with AgNWs of lengths of 2–5 µm and diameters of 20 nm or so, isopropyl alcohol and ethylene glycol as the mixed solvents, and modified polysilane as the wetting agent. We discussed the relationship between the formula of the AgNWs ink and the surface tension, viscosity, contact angle between ink droplet and poly(ethylene) terephthalate (PET) surface, as well as the film-forming properties of the ink. Further, we analyzed the effects of the number of printed layers and the ink concentration of the AgNWs on the microstructures, photoelectric properties and accuracy of the printed patterns, as well as the change in the sheet resistance of the film during different bending cycles. The experimental results show that flexible transparent conductive patterns with a light transmittance of 550 nm of 83.1–88.4% and a sheet resistance of 34.0 Ω∙sq−1–78.3 nm∙sq−1 can be obtained by using AgNWs ink of 0.38 mg∙mL−1 to 0.57 mg∙mL−1, a poly (ethylene terephthalate) (PET) substrate temperature of 40 °C, a nozzle temperature of 35 °C, and heat treated at 60 °C for 10 min. These performances indicate the excellent potential of the inkjet printing of AgNWs networks for developing flexible transparent conductive film.

Published

2021

30. Piezoresistive Characteristics of Nylon Thread Resistive Memories for Wearable Strain Sensors

Author

Ting-Kuo Kang

Subjects

Resistive touchscreen, Interconnection, Materials science, strain sensor, business.industry, graphene, electronic textiles, resistive memory, Surfaces and Interfaces, Piezoresistive effect, Surfaces, Coatings and Films, Resistive random-access memory, piezoresistance, PEDOT:PSS, pedot:pss, Gauge factor, lcsh:TA1-2040, Conductive ink, Materials Chemistry, Optoelectronics, business, lcsh:Engineering (General). Civil engineering (General), Solution process

Abstract

A nylon thread (NT) resistive memory is fabricated by performing a simple dip-and-dry solution process using graphene&ndash, poly(3,4-ethylenedioxythiophene):poly(4-styrenesulfonate) (PEDOT:PSS) conductive ink. The piezoresistive characteristics of the NT resistive memory are further evaluated for wearable strain sensors. While a stretching strain (&epsilon, ) is applied to the NT resistive memory, the relative resistance change of low-resistance state (LRS) is found to be higher than that of high-resistance state (HRS). This result implies that the contribution of the local overlapping interconnection change in graphene and PEDOT:PSS materials to the LRS resistance change is greater than that to the HRS resistance change. In addition, through many cycles of repeatedly stretching and releasing the LRS of the NT resistive memory at a fixed &epsilon, = 7.1%, a gauge factor of approximately 22 is measured and achieved for a highly sensitive and durable strain sensor. Finally, the actual integration of the NT resistive memory into textiles can provide resistive memory and piezoresistive sensor applications simultaneously for wearable electronic textiles.

Published

2019

31. Reactive Conductive Ink Capable of In Situ and Rapid Synthesis of Conductive Patterns Suitable for Inkjet Printing

Author

Zhimin Zhou, Hui Xie, Yuehui Wang, Dexi Du, Yuzhen Zhao, and Jingze Li

Subjects

silver nanoparticles, Materials science, Pharmaceutical Science, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Silver nanoparticle, Article, Analytical Chemistry, lcsh:QD241-441, chemistry.chemical_compound, Sodium borohydride, conductive pattern, lcsh:Organic chemistry, Drug Discovery, Conductive ink, Physical and Theoretical Chemistry, Sheet resistance, inkjet printing, Organic Chemistry, 021001 nanoscience & nanotechnology, reactive ink, 0104 chemical sciences, Silver nitrate, chemistry, Chemical engineering, Models, Chemical, Chemistry (miscellaneous), Screen printing, Molecular Medicine, Printing, Ink, 0210 nano-technology, Ethylene glycol, Algorithms, Photographic paper

Abstract

We report a fabrication method of the conductive pattern based on in situ reactive silver precursor inks by inkjet printing. The reactive silver precursor inks were prepared with ethylene glycol and deionized water mixture as the solvent, and silver nitrate as silver source. Sodium borohydride solution as the reducing agent was first coated on photographic paper by screen printing process, and then dried at 50 &deg, C for 4 h. Furthermore, the reactive silver precursor inks were printed on a photographic paper coated with sodium borohydride using inkjet printing to form silver nanoparticles in situ due to redox reaction, and thus a conductive pattern was obtained. The effects of the reactive silver precursor ink concentration and printing layer number and treatment temperature on the electrical properties and microstructures of the printed patterns were investigated systematically. The size range of in situ-formed silver nanoparticles was 50&ndash, 90 nm. When the reactive silver precursor ink concentration was 0.13 g/mL, the five-layer printed pattern exhibited a sheet resistance of 4.6 &Omega, /&gamma, after drying at room temperature for 2 h, furthermore, the sheet resistance of the printed pattern decreased to 1.4 &Omega, after drying at 130 &deg, C for 2 h. In addition, the display function circuit was printed on the photographic paper to realize the display of the numbers 0&ndash, 99. It provides new research ideas for the development of environmentally friendly and low-cost flexible paper-based circuits.

Published

2019

32. Printing the Ultra-Long Ag Nanowires Inks onto the Flexible Textile Substrate for Stretchable Electronics

Author

Qingwen Xue, Chuan-Yuan Pang, Wei Wu, Pan-Wang Guo, Sheng-Hai Ke, Weijing Yao, and He-Ping Zhu

Subjects

Materials science, Letter, stretchable electronics, General Chemical Engineering, Stretchable electronics, Ag nanowires, Nanowire, screen printing, Nanotechnology, flexible electronics, Flexible electronics, lcsh:Chemistry, lcsh:QD1-999, Printed electronics, Electrode, Conductive ink, Screen printing, General Materials Science, printed electronics, Sheet resistance

Abstract

Printing technology offers a simple and cost-effective opportunity to develop all-printed stretchable circuits and electronic devices, possibly providing ubiquitous, low-cost, and flexible devices. To successfully prepare high-aspect-ratio Ag nanowires (NWs), we used water and anhydrous ethanol as the solvent and polyvinylpyrrolidone (PVP) as the viscosity regulator to obtain a water-soluble Ag NWs conductive ink with good printability. Flexible and stretchable fabric electrodes were directly fabricated through screen printing. After curing at room temperature, the sheet resistance of the Ag NW fabric electrode was 1.5 Ω/sq. Under a tensile strain of 0–80% and with 20% strains applied for 200 cycles, good conductivity was maintained, which was attributed to the inherent flexibility of the Ag NWs and the intrinsic structure of the interlocked texture.

Published

2019

33. Structure Inheritance in Nanoparticle Ink Direct-Writing Processes and Crack-Free Nano-Copper Interconnects Printed by a Single-Run Approach

Author

Liu Shujie, Songling Xing, Guisheng Zou, Yujie Li, Peng Zhang, and Lei Liu

Subjects

nano-copper conductive ink, Materials science, interconnects, education, Nanoparticle, Sintering, 02 engineering and technology, Conductivity, 010402 general chemistry, 01 natural sciences, lcsh:Technology, Article, structure inheritance, direct-writing, Conductive ink, Surface roughness, General Materials Science, Composite material, lcsh:Microscopy, crack-free, lcsh:QC120-168.85, chemistry.chemical_classification, Inkwell, lcsh:QH201-278.5, lcsh:T, Polymer, 021001 nanoscience & nanotechnology, 0104 chemical sciences, body regions, chemistry, lcsh:TA1-2040, Extrusion, lcsh:Descriptive and experimental mechanics, lcsh:Electrical engineering. Electronics. Nuclear engineering, 0210 nano-technology, lcsh:Engineering (General). Civil engineering (General), lcsh:TK1-9971, circulatory and respiratory physiology

Abstract

When nanoparticle conductive ink is used for printing interconnects, cracks and pores are common defects that deteriorate the electrical conductivity of the printed circuits. Influences of the ink solvent, the solid fraction of the ink, the pre-printing treatment and the sintering parameters on the interconnect morphology and conductivity were investigated. It was found that the impacts of all these factors coupled with each other throughout the whole procedure, from the pre-printing to the post-printing processes, and led to a structure inheritance effect. An optimum process route was developed for producing crack-free interconnects by a single-run direct-writing approach using home-made nano-copper ink. A weak gel was promoted in the ink before printing in the presence of long-chain polymers and bridging molecules by mechanical agitation. The fully developed gel network prevented the phase separation during ink extrusion and crack formations during drying. With the reducing agents in the ink and slow evaporation of the ink solvent, compact packing and neck joining of copper nanoparticles were obtained after a two-step sintering process. The crack-free interconnects successfully produced have a surface roughness smaller than 1.5 &mu, m and the square resistances as low as 0.01 &Omega, /□.

Published

2019

34. A Disposable Inkjet-Printed Humidity and Temperature Sensor Fabricated on Paper

Author

Apostolos Segkos, Dimitris Barmpakos, Christos Tsamis, and Grigoris Kaltsas

Subjects

Materials science, Temperature sensing, business.industry, humidity, Humidity, temperature, lcsh:A, Bending, Repeatability, inkjet-printed sensors, Signal, Printed electronics, Conductive ink, paper sensor, Optoelectronics, Relative humidity, printed electronics, lcsh:General Works, business

Abstract

In this work we present the development of a low-cost humidity and temperature sensing platform on paper by inkjet printing, using a commercial AgNPs conductive ink. The humidity sensing module was capable of measuring relative humidity in the range of 0⁻90%rH, exhibiting linear response with minimal memory effect when returning to 0%rH baseline signal while the temperature sensor performed linearly as well in the range of 25⁻75°C. Process repeatability has been verified by electrical and optical characterization. Mechanical bending results highlight the platform’s capability to serve as an easy to install, flexible multi-parametric sensing platform.

Published

2018

35. 3D Printed Long-Range Cavity Structure UHF RFID Tag Antenna with Painting Conductive Ink on Convex Surface

Author

You Chung Chung and Franck Kimetya Byondi

Subjects

energy harvesting, Surface (mathematics), Materials science, RFID tag antenna, Acoustics, lcsh:Chemical technology, Biochemistry, Article, painted RFID tag antenna, Analytical Chemistry, long-range RFID tag, concave antenna, Conductive ink, Radio-frequency identification, lcsh:TP1-1185, Electrical and Electronic Engineering, Instrumentation, IoT RFID sensor, RFID sensors, Range (particle radiation), RFID metal tag, business.industry, Reading (computer), convex tag antenna, 3D antenna, Atomic and Molecular Physics, and Optics, Ultra high frequency, cavity antenna, Antenna (radio), business, Energy harvesting

Abstract

In this paper, we describe a long-range convex cavity-type passive ultra-high-frequency (UHF) radio frequency identification (RFID) tag to use on various metal and non-metal surfaces, for IoT sensor energy harvesting. The tag antenna is built on the 3D printed cavity structure with polylactic acid (PLA) plastic and painted with the conductive ink on the 1 mm protruding area (convex) of inner surface and the side-walls of the cavity structure to form a cavity structure. The tag is designed to operate in the UHF band (840–960 MHz). This long-range cavity tag antenna (CTA) works at both 920 MHz and 915 MHz UHF RFID frequencies. It provides a linear polarized (LP) frontal reading range of 35 m and side reading range above 15 m when mounted on either metal or non-metal objects. We describe the antenna characteristics, structure, modeling, simulation, and experimental results. A mathematical reading range also was calculated and compared with experimental data.

Published

2021

36. Direct Laser Interference Ink Printing Using Copper Metal-Organic Decomposition Ink for Nanofabrication.

Author

Park JH, Lee JW, Ma YW, Kang BS, Hong SM, and Shin BS

Abstract

In this study, we developed an effective and rapid process for nanoscale ink printing, direct laser interference ink printing (DLIIP), which involves the photothermal reaction of a copper-based metal-organic decomposition ink. A periodically lined copper pattern with a width of 500 nm was printed on a 240 μm-wide line at a fabrication speed of 17 mm/s under an ambient environment and without any pre- or post-processing steps. This pattern had a resistivity of 3.5 μΩ∙cm, and it was found to exhibit a low oxidation state that was twice as high as that of bulk copper. These results demonstrate the feasibility of DLIIP for nanoscale copper printing with fine electrical characteristics.

Published

2022

37. Facile Synthesis of Silver Nanoparticles and Preparation of Conductive Ink.

Author

Hong GB, Luo YH, Chuang KJ, Cheng HY, Chang KC, and Ma CM

Abstract

In the scientific industry, sustainable nanotechnology has attracted great attention and has been successful in facilitating solutions to challenges presented in various fields. For the present work, silver nanoparticles (AgNPs) were prepared using a chemical reduction synthesis method. Then, a low-temperature sintering process was deployed to obtain an Ag-conductive ink preparation which could be applied to a flexible substrate. The size and shape of the AgNPs were characterized by ultraviolet-visible spectrophotometry (UV-Vis) and transmission electron microscopy (TEM). The experiments indicated that the size and agglomeration of the AgNPs could be well controlled by varying the reaction time, reaction temperature, and pH value. The rate of nanoparticle generation was the highest when the reaction temperature was 100 °C within the 40 min reaction time, achieving the most satisfactorily dispersed nanoparticles and nanoballs with an average size of 60.25 nm at a pH value of 8. Moreover, the electrical resistivity of the obtained Ag-conductive ink is controllable, under the optimal sintering temperature and time (85 °C for 5 min), leading to an optimal electrical resistivity of 9.9 × 10 -6 Ω cm. The results obtained in this study, considering AgNPs and Ag-conductive ink, may also be extended to other metals in future research.

Published

2022

38. Innovative Eco-Friendly Conductive Ink Based on Carbonized Lignin for the Production of Flexible and Stretchable Bio-Sensors.

Author

Zappi D, Varani G, Cozzoni E, Iatsunskyi I, Laschi S, and Giardi MT

Abstract

In this study, we report a novel way to produce carbon-based conductive inks for electronic and sensor technology applications. Carbonized lignin, obtained from the waste products of the Eucalyptus globulus tree paper industry, was used to produce a stable conductive ink. To this end, liquid-phase compositions were tested with different amounts of carbonized lignin powder to obtain an ink with optimal conductivity and rheological properties for different possible uses. The combination that showed the best properties, both regarding electrochemical properties and green compatibility of the materials employed, was cyclohexanone/cellulose acetate/carbonized lignin 5% ( w/w ), which was used to produce screen-printed electrodes. The electrodes were characterized from a structural and electrochemical point of view, resulting in an electrochemically active area of 0.1813 cm 2 , compared to the electrochemically active area of 0.1420 cm 2 obtained by employing geometrically similar petroleum-based screen-printed electrodes and, finally, their performance was demonstrated for the quantification of uric acid, with a limit of detection of 0.3 μM, and their biocompatibility was assessed by testing it with the laccase enzyme and achieving a limit of detection of 2.01 μM for catechol as the substrate. The results suggest that the developed ink could be of great use in both sensor and electronic industries, reducing the overall ecological impact of traditionally used petroleum-based inks.

Published

2021

39. Syntheses of Silver Nanowires Ink and Printable Flexible Transparent Conductive Film: A Review

Author

Xiaoli Wu, Zhimin Zhou, Jingze Li, and Yuehui Wang

Subjects

Materials science, Inkwell, printed electronic technology, conductive ink, Touch panel, Nanotechnology, Surfaces and Interfaces, Silver nanowires, silver nanowires, Surfaces, Coatings and Films, lcsh:TA1-2040, Screen printing, Conductive ink, Materials Chemistry, flexible transparent conductive film, Electronics, lcsh:Engineering (General). Civil engineering (General), Electrical conductor, Inkjet printing

Abstract

Nowadays, flexible transparent conductive film (FTCF) is one of the important components of many flexible electronic devices. Due to comprehensive performances on optoelectronics, FTCF based on silver nanowires (AgNWs) networks have received great attention and are expected to be a new generation of transparent conductive film materials. Due to its simple process, printed electronic technology is now an important technology for the rapid production of low-cost and high-quality flexible electronic devices. AgNWs-based FTCF fabricated by using printed electronic technology is considered to be the most promising process. Here, the preparation and performance of AgNW ink are introduced. The current printing technologies are described, including gravure printing, screen printing and inkjet printing. In addition, the latest methods to improve the conductivity, adhesion, and stability of AgNWs-based FTCF are introduced. Finally, the applications of AgNWs-based FTCF in solar cells, transparent film heaters, optoelectronic devices, touch panel, and sensors are introduced in detail. Therefore, combining various printing technologies with AgNWs ink may provide more opportunities for the development of flexible electronic devices in the future.

Published

2020

40. Development and Characterization of a Novel Low-Cost Water-Level and Water Quality Monitoring Sensor by Using Enhanced Screen Printing Technology with PEDOT:PSS

Author

Bei Wang, Manuel Baeuscher, Piotr Mackowiak, Xiaodong Hu, Klaus-Dieter Lang, Ha-Duong Ngo, Moritz Hubl, Markus Woehrmann, Martin Schneider-Ramelow, Nils Juergensen, Katharina Becker, and Publica

Subjects

Materials science, lcsh:Mechanical engineering and machinery, Capacitive sensing, water quality monitoring, 02 engineering and technology, Substrate (printing), 01 natural sciences, Article, PEDOT:PSS, Conductive ink, lcsh:TJ1-1570, conductive polymer, Electrical and Electronic Engineering, Sheet resistance, Conductive polymer, business.industry, Mechanical Engineering, 010401 analytical chemistry, screen printing, capacitive sensor, adhesive peeling force test, poly(3,4-ethylenedioxythiophene):poly(styrenesulfonate) (PEDOT:PSS), 021001 nanoscience & nanotechnology, 0104 chemical sciences, Control and Systems Engineering, Screen printing, Optoelectronics, Adhesive, ddc:620, 0210 nano-technology, business, water-level sensor

Abstract

A novel capacitive sensor for measuring the water-level and monitoring the water quality has been developed in this work by using an enhanced screen printing technology. A commonly used environment-friendly conductive polymer poly(3,4-ethylenedioxythiophene):poly (styrenesulfonate) (PEDOT:PSS) for conductive sensors has a limited conductivity due to its high sheet resistance. A physical treatment performed during the printing process has reduced the sheet resistance of printed PEDOT:PSS on polyethylenterephthalat (PET) substrate from 264.39 Ω/sq to 23.44 Ω/sq. The adhesion bonding force between printed PEDOT:PSS and the substrate PET is increased by using chemical treatment and tested using a newly designed adhesive peeling force test. Using the economical conductive ink PEDOT:PSS with this new physical treatment, our capacitive sensors are cost-efficient and have a sensitivity of up to 1.25 pF/mm.

Published

2020

41. High-Yield Production of Aqueous Graphene for Electrohydrodynamic Drop-on-Demand Printing of Biocompatible Conductive Patterns

Author

Pei Lun Lai, Amir Ehsan Niaraki Asli, Nicole N. Hashemi, Jingshuai Guo, and Reza Montazami

Subjects

Materials science, Surface Properties, Scanning electron microscope, lcsh:Biotechnology, Clinical Biochemistry, Biocompatible Materials, Biosensing Techniques, neuronal sensing, 02 engineering and technology, 010402 general chemistry, flexible electronics, 01 natural sciences, Article, law.invention, symbols.namesake, law, lcsh:TP248.13-248.65, Conductive ink, Animals, Graphite, Particle Size, Cells, Cultured, Sheet resistance, inkjet printing, Graphene, Cell Membrane, graphene, Electric Conductivity, Water, conductive ink, Serum Albumin, Bovine, General Medicine, 021001 nanoscience & nanotechnology, Flexible electronics, Rats, 0104 chemical sciences, Chemical engineering, Printing, Three-Dimensional, Hydrodynamics, symbols, Cattle, 0210 nano-technology, Raman spectroscopy, Polyimide

Abstract

Presented here is a scalable and aqueous phase exfoliation of graphite to high yield and quality of few layer graphene (FLG) using Bovine Serum Albomine (BSA) and wet ball milling. The produced graphene ink is tailored for printable and flexible electronics, having shown promising results in terms of electrical conductivity and temporal stability. Shear force generated by steel balls which resulted in 2&ndash, 3 layer defect-free graphene platelets with an average size of hundreds of nm, and with a concentration of about 5.1 mg/mL characterized by Raman spectroscopy, atomic force microscopy (AFM), transmittance electron microscopy (TEM) and UV-vis spectroscopy. Further, a conductive ink was prepared and printed on flexible substrate (Polyimide) with controlled resolution. Scanning electron microscopy (SEM) and Profilometry revealed the effect of thermal annealing on the prints to concede consistent morphological characteristics. The resulted sheet resistance was measured to be R s &nbsp, = &nbsp, 36.75 &nbsp, &Omega, / sqr for prints as long as 100 mm. Printable inks were produced in volumes ranging from 20 mL to 1 L, with potential to facilitate large scale production of graphene for applications in biosensors, as well as flexible and printable electronics.

Published

2020

42. Inkjet Printing of Flexible Transparent Conductive Films with Silver Nanowires Ink.

Author

Wu X, Wang S, Luo Z, Lu J, Lin K, Xie H, Wang Y, and Li JZ

Abstract

The inkjet printing process is a promising electronic printing technique for large-scale, printed, flexible and stretchable electronics because of features such as its high manufacturing speed, environmental friendliness, simple process, low cost, accurate positioning, and so on. As the base material of printed conductive patterns, conductive ink is the foundation of the development of printed electronics technology, and directly affects the performance and the quality of electronic products. In this paper, conductive ink with silver nanowires (AgNWs) was prepared, with AgNWs of lengths of 2-5 µm and diameters of 20 nm or so, isopropyl alcohol and ethylene glycol as the mixed solvents, and modified polysilane as the wetting agent. We discussed the relationship between the formula of the AgNWs ink and the surface tension, viscosity, contact angle between ink droplet and poly(ethylene) terephthalate (PET) surface, as well as the film-forming properties of the ink. Further, we analyzed the effects of the number of printed layers and the ink concentration of the AgNWs on the microstructures, photoelectric properties and accuracy of the printed patterns, as well as the change in the sheet resistance of the film during different bending cycles. The experimental results show that flexible transparent conductive patterns with a light transmittance of 550 nm of 83.1-88.4% and a sheet resistance of 34.0 Ω∙sq -1 -78.3 nm∙sq -1 can be obtained by using AgNWs ink of 0.38 mg∙mL -1 to 0.57 mg∙mL -1 , a poly (ethylene terephthalate) (PET) substrate temperature of 40 °C, a nozzle temperature of 35 °C, and heat treated at 60 °C for 10 min. These performances indicate the excellent potential of the inkjet printing of AgNWs networks for developing flexible transparent conductive film.

Published

2021

43. Research of a Novel 3D Printed Strain Gauge Type Force Sensor

Author

Mingjie Liu, Zhang Qi, Shao Yiwei, Chuanqi Liu, and Yulong Zhao

Subjects

digital light processing, Materials science, Cost effectiveness, lcsh:Mechanical engineering and machinery, sensor fabrication, 3D printing, 02 engineering and technology, Substrate (printing), 01 natural sciences, Article, PEDOT:PSS, Conductive ink, lcsh:TJ1-1570, 3D printed force sensor, Electrical and Electronic Engineering, Strain gauge, inkjet printing, business.industry, Mechanical Engineering, 010401 analytical chemistry, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Control and Systems Engineering, Gauge factor, Optoelectronics, Digital Light Processing, 0210 nano-technology, business

Abstract

A 3D printed force sensor with a composite structure developed by combining digital light processing (DLP) based printing and inkjet printing technologies is described in this paper. The sensor has cost effectiveness and time-saving advantages compared to the traditional sensor manufacturing process. During this work, the substrate of the force sensor was printed by a DLP based 3D printer using a transparent high-temperature resin, and the strain gauge of the force sensor was inkjet printed using poly(3,4-ethylenedioxythiophene) polystyrene sulfonate (PEDOT/PSS) conductive ink. Finite element (FE) simulation was conducted to find the print origin of the strain gauge. The relationship between the mechanical properties of the post-cured resin and the curing time was investigated and the resistance of the printed strain gauges was characterized to optimize process parameters. Afterward, the force sensor was characterized. Experimental results show that the sensitivity of the sensor is 2.92% N&minus, 1 and the linearity error is 3.1485% full scale (FS) within the range from 0 mN&ndash, 160 mN, and the effective gauge factor of the strain gauge is about 0.98. The resistance drifting is less than 0.004 k&Omega, within an hour. These figures prove that the device can perform as a force sensor and 3D printing technology may have great applied potential in sensor fabrication.

Published

2018

44. On-Demand Multi-Resolution Liquid Alloy Printing Based on Viscoelastic Flow Squeezing

Author

Zhigang Wu, Zhang Pan, Chuan Fei Guo, Kang Wu, and Fen Li

Subjects

Work (thermodynamics), liquid alloy, Materials science, stretchable electronics, Polymers and Plastics, Stretchable electronics, Nozzle, Mechanical engineering, 02 engineering and technology, printing, multi-resolution, squeezing effect, 010402 general chemistry, 01 natural sciences, Article, lcsh:QD241-441, Physics::Fluid Dynamics, lcsh:Organic chemistry, Conductive ink, Viscoelastic flow, Electronic circuit, General Chemistry, Liquid alloy, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Current (fluid), 0210 nano-technology

Abstract

Recently, high-resolution patterning techniques of stretchable electronics advanced extensively. An important trend is to fabricate complex circuits with varied sizes in a small area, which is a technical challenge to current conductive ink printing technologies. Here, we introduce a new strategy for multi-resolution liquid alloy printing, which can tune the resolution of printed liquid alloy trace in real time with the squeezing effect of compound viscoelastic flow. A newly developed coaxial nozzle with the inner nozzle extension (CNINE) is used to wrap and squeeze liquid alloy steadily and effectively. By controlling the working parameters and compound flow properties, liquid alloy patterns with different widths are obtained continuously. This work offers a new way to rapidly manufacture complex stretchable electronics patterning in multi-resolution.

Published

2018