Inkjet Printing on a New Flexible Ceramic Substrate for Internet of Things (IoT) Applications

Kirtania, Sharadindu Gopal; Riheen, Manjurul Ahsan; Kim, Sun Ung; Sekhar, Karthik; Wiśniewska, Anna; Sekhar, Praveen Kumar

doi:10.3390/mi11090841

Cited by 20 publications

(11 citation statements)

References 40 publications

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“…Flexible ceramics substrates are also another preference. Some flexible ceramics substrates developed today include zirconia‐based [ 210 ] and inorganic mica. [ 211,212 ] High strength and flat surface up to atomic scale is the requirement to obtain high crystalline thin‐film.…”

Section: Fabrication Of Flexible and Wearable Mxenes‐based Gas Sensin...mentioning

confidence: 99%

Prospects and Challenges of MXenes as Emerging Sensing Materials for Flexible and Wearable Breath‐Based Biomarker Diagnosis

Hermawan

Amrillah

Riapanitra

et al. 2021

Adv Healthcare Materials

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A fully integrated, flexible, and functional sensing device for exhaled breath analysis drastically transforms conventional medical diagnosis to non-invasive, low-cost, real-time, and personalized health care. 2D materials based on MXenes offer multiple advantages for accurately detecting various breath biomarkers compared to conventional semiconducting oxides. High surface sensitivity, large surface-to-weight ratio, room temperature detection, and easy-to-assemble structures are vital parameters for such sensing devices in which MXenes have demonstrated all these properties both experimentally and theoretically. So far, MXenes-based flexible sensor is successfully fabricated at a lab-scale and is predicted to be translated into clinical practice within the next few years. This review presents a potential application of MXenes as emerging materials for flexible and wearable sensor devices. The biomarkers from exhaled breath are described first, with emphasis on metabolic processes and diseases indicated by abnormal biomarkers. Then, biomarkers sensing performances provided by MXenes families and the enhancement strategies are discussed. The method of fabrications toward MXenes integration into various flexible substrates is summarized. Finally, the fundamental challenges and prospects, including portable integration with Internet-of-Thing (IoT) and Artificial Intelligence (AI), are addressed to realize marketization.

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Section: Fabrication Of Flexible and Wearable Mxenes‐based Gas Sensin...mentioning

confidence: 99%

Prospects and Challenges of MXenes as Emerging Sensing Materials for Flexible and Wearable Breath‐Based Biomarker Diagnosis

Hermawan

Amrillah

Riapanitra

et al. 2021

Adv Healthcare Materials

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“…One important step to achieve high TCR of inkjet-printed temperature sensors is the sintering of the printed nanoparticles. High sintering temperatures increase the density and the conductivity of inkjet-printed nanoparticle structures due to higher driving forces during sintering [ 15 ]. Matthiessen’s rule states that the sensitivity of an electrical resistance to temperature only depends on the scattering of phonons [ 16 ].…”

Section: Introductionmentioning

confidence: 99%

“…Other important sintering parameters to achieve high sintering densities are dwell time and heating rates. A dwell time of usually 10 to 30 min should be reached so that sintering can occur [ 15 , 17 ]. High heating rates are preferable, since slow heating rates can result in rounding of pores during the first phase of sintering [ 18 ].…”

Section: Introductionmentioning

confidence: 99%

Inkjet-Printed Temperature Sensors Characterized according to Standards

Jaeger

Schwenck

Walter

et al. 2022

Sensors

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This paper describes the characterization of inkjet-printed resistive temperature sensors according to the international standard IEC 61928-2. The goal is to evaluate such sensors comprehensively, to identify important manufacturing processes, and to generate data for inkjet-printed temperature sensors according to the mentioned standard for the first time, which will enable future comparisons across different publications. Temperature sensors were printed with a silver nanoparticle ink on injection-molded parts. After printing, the sensors were sintered with different parameters to investigate their influences on the performance. Temperature sensors were characterized in a temperature range from 10 °C to 85 °C at 60% RH. It turned out that the highest tested sintering temperature of 200 °C, the longest dwell time of 24 h, and a coating with fluoropolymer resulted in the best sensor properties, which are a high temperature coefficient of resistance, low hysteresis, low non-repeatability, and low maximum error. The determined hysteresis, non-repeatability, and maximum error are below 1.4% of the full-scale output (FSO), and the temperature coefficient of resistance is 1.23–1.31 × 10−3 K−1. These results show that inkjet printing is a capable technology for the manufacturing of temperature sensors for applications up to 85 °C, such as lab-on-a-chip devices.

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“…In this case where a metallic nanoparticlebased ink was printed on a non-porous surface, mechanical interlocking is the most dominant adhesion mechanism as there was no surface treatment done prior to printing. This is supported by Halonen et al [42], Niittynen et al [43] and Gopal Kirtania et al [44] who also reported that the sintering time and sintering duration are the most influential factors for adhesion improvement.…”

Section: Adhesion Classificationmentioning

confidence: 65%

Integrated Fabrication of Novel Inkjet-Printed Silver Nanoparticle Sensors on Carbon Fiber Reinforced Nylon Composites

et al. 2021

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Inkjet-printing technology enables the contactless deposition of functional materials such as conductive inks on surfaces, hence reducing contamination and the risk of substrate damage. In printed electronics, inkjet technology offers the significant advantage of controlling the volume of material deposited, and therefore the fine-tuning of the printed geometry, which is crucial for the performance of the final printed electronics. Inkjet printing of functional inks can be used to produce sensors to detect failure of mechanical structures such as carbon fiber reinforced composite (CFRC) components, instead of using attached sensors, which are subject to delamination. Here, silver nanoparticle-based strain sensors were embedded directly in an insulated carbon-fiber laminate by using inkjet printing to achieve an optimized conductive and adhesive geometry, forming a piezoresistive strain sensor. Following the inkjet-printing optimization process, the sensor conductivity and adhesion performance were evaluated. Finally, the sensor was quantified by using a bending rig which applied a pre-determined strain, with the response indicating an accurate sensitivity as the resistance increased with an increased strain. The ability to embed the sensor directly on the CFRC prevents the use of interfacial adhesives which is the main source of failure due to delamination.

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Inkjet Printing on a New Flexible Ceramic Substrate for Internet of Things (IoT) Applications

Cited by 20 publications

References 40 publications

Prospects and Challenges of MXenes as Emerging Sensing Materials for Flexible and Wearable Breath‐Based Biomarker Diagnosis

Prospects and Challenges of MXenes as Emerging Sensing Materials for Flexible and Wearable Breath‐Based Biomarker Diagnosis

Inkjet-Printed Temperature Sensors Characterized according to Standards

Integrated Fabrication of Novel Inkjet-Printed Silver Nanoparticle Sensors on Carbon Fiber Reinforced Nylon Composites

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