Showing total 6 results

1. Nacre-inspired hierarchical bionic substrate for enhanced thermal and mechanical stability in flexible applications.

Author

Sun, Baichuan, Xu, Gaobin, Guan, Cunhe, Ji, Xu, Yang, Zhaohui, Chen, Shirong, Chen, Xing, Ma, Yuanming, Yu, Yongqiang, and Feng, Jianguo

Subjects

*ELASTIC modulus, *FLEXIBLE electronics, *BIOMIMETICS, *SUBSTRATES (Materials science), *DIFFERENTIAL scanning calorimetry

Abstract

Flexible substrates, essential for flexible electronics by providing support and flexibility while influencing sensor stability, still face challenges in achieving mechanical and thermal stability, particularly in large-scale production and cost control. Inspired by the nacre's "brick-and-mortar" hierarchical microstructure, this study introduces PPSN (paper/polydimethylsiloxane (PDMS)/Si₃N₄ nanoparticles), a novel flexible substrate that mimics the "brick-and-mortar" structure. PPSN, with its topological interlocking and assembly technique, provides excellent thermal and mechanical stability, including high-temperature resistance and stress dissipation. An optimized Si₃N₄ content of 1.0 wt% yields a peak elastic modulus of 1245.27 MPa while maintaining hydrophobicity, with a contact angle of 127.1° at 3.0 wt%. The substrate shows excellent fatigue durability, retaining its morphology after 10,000 bending cycles. Thermal analysis indicates a stable CTE below 20 ppm/°C up to 300°C, rising to 200 ppm/°C between 350 and 400°C. Differential scanning calorimetry (DSC) and thermogravimetric analysis (TGA) reveal minimal thermal decomposition with mass loss below 0.5 % from 25 to 300°C and under 3 % at 400°C. Additionally, electrodes were printed on the substrate using screen printing and ion beam deposition (IBD), demonstrating good material adhesion. A flexible temperature sensor was fabricated and exhibited good sensitivity and stability with a TCR of −0.262 % °C⁻¹. PPSN advances traditional materials with superior mechanical strength, thermal stability, and durability, offering significant scientific and practical value for flexible electronics and low-cost biomimetic processes. [Display omitted] • PPSN mimics nacre's structure, offering high thermal and mechanical stability. • Peak elastic modulus at 1.0 wt% Si₃N₄, with hydrophobicity and durability. • Stable CTE below 20 ppm/°C up to 300°C with minimal thermal mass loss. • Excellent performance in flexible sensors with a TCR of −0.262 % °C⁻¹. [ABSTRACT FROM AUTHOR]

Published

2024

2. Folding triboelectric nanogenerator on paper based on conductive ink and teflon tape.

Author

Xia, Kequan, Zhang, Hongze, Zhu, Zhiyuan, and Xu, Zhiwei

Subjects

*TRIBOELECTRICITY, *CONDUCTIVE ink, *POLYTEF, *LIGHT emitting diodes, *FLEXIBLE electronics

Abstract

Recently, triboelectric nanogenerator (TENG) has aroused considerable interest due to various advantages. Particularly, one benefit which sand out is that the triboelectric pair of TENG is very tolerant to the material composition. Thus, it is possible and significant to develop cost-effective TENG using commercial and inexpensive material. In this work, we present a paper TENG by repeated folding completely using commercially available commodity materials, such as paper, brush pen, Teflon tape, and conductive ink. Paper is used as functionally triboelectric pair and spring-like supporting structure. The stacked paper TENG is fabricated and large enhancement of output performance is observed. The generated electric outputs have been used to directly light-up commercial LEDs. The proposed TENG has demonstrated simplicity and cost-effective, which is suitable for flexible electronics. [ABSTRACT FROM AUTHOR]

Published

2018

3. Screen printing of flexible piezoelectric based device on polyethylene terephthalate (PET) and paper for touch and force sensing applications.

Author

Emamian, Sepehr, Narakathu, Binu Baby, Chlaihawi, Amer Abdulmahdi, Bazuin, Bradley J., and Atashbar, Massood Zandi

Subjects

*POLYETHYLENE terephthalate, *DIELECTRIC materials, *PIEZOELECTRIC devices, *POLYVINYLIDENE fluoride, *FINITE element method, *X-ray diffraction

Abstract

A fully printed piezoelectric based touch sensor device has been successfully fabricated on flexible polyethylene terephthalate (PET) and paper substrates using screen printing technique. The device, consisting of a 4 × 4 array of printed sensors and interconnect lines, was fabricated using silver (Ag) ink. Screen printed polyvinylidene fluoride (PVDF), as a piezoelectric layer, was sandwiched between the printed Ag top and bottom electrode metallization layers. A linear relationship between the sensor response and varying applied forces to the device was obtained through finite element analysis (FEA) method simulation. X-ray diffraction (XRD) analysis was performed to verify the formation of the β-phase crystals in the PVDF layer during the curing process. The effective polarization of the printed piezoelectric layer was analyzed using capacitance-voltage analysis. A sensitivity of 1.2 V/N and 0.3 V/N, with correlation coefficient of 0.9954 and 0.9859, was obtained for the PET and paper based printed touch sensors, respectively. The piezoelectric-voltage analysis demonstrated that the printed sensors can be used for both touch and force based applications. [ABSTRACT FROM AUTHOR]

Published

2017

4. Green paper-based piezoelectronics for sensors and actuators.

Author

Lemaire, E., Moser, R., Borsa, C.J., and Briand, D.

Subjects

*CHEMICAL detectors, *ACTUATORS, *PIEZOELECTRIC composites, *ROCHELLE salt, *CRYSTALLIZATION

Abstract

We report a novel biodegradable piezoelectric composite fabricated from paper and the piezoelectric salt, sodium potassium tartrate tetrahydrate (Rochelle salt, which we term PiezoSalt). The piezoelectric composite is non-toxic and is fabricated free of environmentally harmful solvents by impregnating PiezoSalt into a paper matrix through the crystallization of a concentrated PiezoSalt brine solution. The composite exhibits an effective piezoelectric constant between 3 and 25 pC N −1 , dielectric constant of 7, mass density of 625 kg m −3 , and a Young’s modulus between 7 and 8 GPa. When directly actuated, cm-scale cantilevers consisting of PiezoSalt paper produced clearly audible sound waves, illustrating one potential application. PiezoSalt paper composite provides a scalable, high throughput approach for biodegradable sensors and transducers with unsurpassed environmentally friendly processing. [ABSTRACT FROM AUTHOR]

Published

2016

5. Au pattern fabrication on a cellulose paper using micro-contact printing technique: Solvent swell effect

Author

Lim, H.G., Cho, G.Y., Kim, Jaehwan, and Kang, K.S.

Subjects

*CELLULOSE, *PAPER, *MICROELECTRONICS, *PRINTING, *SOLVENTS, *GOLD, *PATTERNMAKING, *SMART materials

Abstract

Abstract: Cellulose paper has been discovered as a smart material including actuating behavior and electro-active paper (EAPap) with application of electric field. To control the electro-active motion, the EAPap requires electronic components on the paper. However, conventional lithography technique cannot apply to the paper to fabricate electronic components due to its hydrophilic nature, water absorption, and flexibility. For this reason, a micro-contact printing (MCP) technique was employed to fabricate Au patterns on the EAPap. Large number of Au-islands and irregular edge patterns were observed on the transferred Au-pattern when the self-assembled monolayer (SAM) was fabricated on the cellulose surface. Therefore, SAM was fabricated on the Au-surface. The surface quality of the transferred Au was strongly dependent on the solvent polarity. Better surface morphology of the transferred Au-pattern was obtained with the polar solvent compared with nonpolar solvent. [Copyright &y& Elsevier]

Published

2009

6. High sensitivity flexible paper temperature sensor and body-attachable patch for thermometers.

Author

Lee, Jin-Woo, Choi, Younguk, Jang, Jaehoon, Yeom, Se-Hyuk, Lee, Wanghoon, and Ju, Byeong-Kwon

Subjects

*TEMPERATURE sensors, *THERMOMETERS, *FLEXIBLE electronics, *HUMIDITY, *SIGNAL processing, *HEAT treatment

Abstract

• Fabrication of flexible paper temperature sensors with 658.5 Ω/°C. • Temperature sensitivity of 658.5 Ω/°C, which is 14 times higher than that of sensor with polymer substrate (46.0 Ω/°C), for the temperature range of 30–42 °C. • Reliable process against atmospheric humidity. • Implement a body-attachable temperature patch for wearable thermometer. A highly sensitive, flexible, and wearable paper-based temperature sensor is fabricated using printing paper and poly(3,4-ethylenedioxythiophene):poly(4-styrenesulfonate) (PEDOT:PSS) solution. It exhibits a negative temperature coefficient and is implemented in a new band-like body-attachable thermometer. Compared to the polymer substrate, the use of hydrophilic and flexible paper substrate facilitates significantly superior sensitivity and simple fabrication. The paper sensor is fabricated by depositing PEDOT:PSS onto the paper with an 80 g base weight for 40 s, which is covered with a 50 μm film to protect it from humidity. This is followed by a heat treatment at 150 °C for 10 min. The paper sensor exhibited an electrical conductivity of 0.48 Ωcm−1 at room temperature with a linearity of 99.86 %. Remarkably, its sensitivity is 658.5 Ω/°C, which is 14 times higher than that of sensor with polyimide substrate (46 Ω/°C), for the body temperature range of 30–42 °C. The paper-based temperature sensor is implemented in a body-attachable patch for a wearable thermometer, which is simply connected with a circuit part for signal processing and the results are transferred to a phone via Bluetooth. The proposed inexpensive sensor is potentially useful for a wide range of flexible electronics and healthcare applications. [ABSTRACT FROM AUTHOR]

Published

2020