Flexible and Green Electronics Manufactured by Origami Folding of Nanosilicate-Reinforced Cellulose Paper

Kadumudi, Firoz Babu; Trifol, Jon; Jahanshahi, Mohammadjavad; Zsurzsan, Gabriel; Mehrali, Mehdi; Zeqiraj, Eva; Shaki, Hossein; Alehosseini, Morteza; Gundlach, Carsten; Li, Qiang; Dong, Mingdong; Akbari, Mohsen; Knott, Arnold; Almdal, Kristoffer; Dolatshahi-Pirouz, Alireza

doi:10.1021/acsami.0c15326

Cited by 24 publications

(24 citation statements)

References 57 publications

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“…In addition to implementing printing/ handwriting technologies for the manufacturing of low-cost and flexible cellulose-based circuits, there is a growing need to integrate resourceconscious strategies when these electronic devices reach their end-of-life. Given the well-known potential of paper/cellulose in achieving a circular economy, [21,37,61,62,77] we used a simple and environment-friendly process to properly separate the CICH sticker from the paper circuits, and then moved to a water-based recycling strategy, reusing all the recovered materials to prepare new devices (Figure S5 and Video S1, Supporting Information). The printed EGTs exhibit n-type behavior and operate in the enhancement mode (normally-off), which is confirmed by positive V on (≈0.8 V), leading to more stable operation.…”

Section: Design Of Recyclable Pencil-drawn Resistor-loaded Circuits With Printed Zno Egts On Office Papermentioning

confidence: 99%

Handwritten and Sustainable Electronic Logic Circuits with Fully Printed Paper Transistors

Cunha¹,

Martins²,

Bahubalindruni

et al. 2021

Adv Materials Technologies

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Printed electronics answers to the emerging trend of using truly inexpensive and easily accessible techniques to design and fabricate low‐cost and recyclable flexible electronic components. Nevertheless, printing of inorganic semiconductor materials arises some barriers for flexible electronics, as they usually may require high annealing temperatures to enhance their electronic performances, which are not compatible with paper. Here, the formulation of a water‐based, screen‐printable ink loaded with zinc oxide nanoparticles that does not require any sintering process is reported. The ink is used to create the channel in fully printed electrolyte‐gated transistors on paper, gated by a cellulose‐based ionic conductive sticker. The high conformability of the electrolyte‐sticker mitigates the effect of the surface roughness of the channel, yielding transistors that operate under low voltage (<2.5 V) with a current modulation above 104 and μSat ≈ 22 cm2 V−1 s−1. These devices operate even under moderate outward bending conditions. The screen‐printed transistors are readily integrated in “universal” logic gates (NOR and NAND) by using ubiquitous calligraphy accessories for patterning of conductive paths and graphitic load resistances. This demonstrates the manufacturing of reliable and recyclable cellulose‐based iontronic circuits with low power consumption, paving the way to a new era of sustainable “green” electronics.

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Section: Design Of Recyclable Pencil-drawn Resistor-loaded Circuits With Printed Zno Egts On Office Papermentioning

confidence: 99%

Handwritten and Sustainable Electronic Logic Circuits with Fully Printed Paper Transistors

Cunha¹,

Martins²,

Bahubalindruni

et al. 2021

Adv Materials Technologies

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“…Compared to 10 various types of synthetic composite polymers in previous studies, this particular SPI–HBT0.5–GL0.5 film exhibited comparable (even higher) conductivity, which reached 0.912 S/m under a low conductive filler loading (0.5 wt %) and high moisture content (48.2%) (Figure b and Table S5). ,− The conductivity of the poly ( l -lactic acid) (PLLA) polymer (sample 5 in Figure b and Table S6) was as high as 0.96 S/m at a 10% loading of supramolecular polymer-functionalized graphene (SPFG); however, the conductivity decreased to 5.62 × 10 –5 S/m when the loading was 1% (sample 4 in Figure b and Table S6), which was far inferior to the SPI–HBT0.5–GL0.5 film. The conductivity of the SPI–HBT0.5–GL0.5 film was also much higher than that of several biobased conductive composites (such as silk, electrical protein NWs, cellulose, starch, bio-oil, and so on.)…”

Section: Results and Discussionmentioning

confidence: 99%

“Green” Flexible Electronics: Biodegradable and Mechanically Strong Soy Protein-Based Nanocomposite Films for Human Motion Monitoring

Wei

Jiang

et al. 2021

ACS Appl. Mater. Interfaces

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Soy protein isolate (SPI) is envisioned as a promising alternative to fabricate “green” flexible electronics, showing great potential in the field of flexible wearable electronics. However, it is challenging to simultaneously achieve conductive film-based human motion-monitoring strain sensors with reliable fatigue resistance, robust mechanical property, environmental degradability, and sensing capability of human motions. Herein, we prepared a series of SPI-based nanocomposite films by embedding a surface-hydroxylated high-dielectric constant inorganic filler, BaTiO3, (HBT) as interspersed nanoparticles into a biodegradable SPI substrate. In particular, the fabricated film comprising 0.5 wt % HBT and glycerin (GL), namely, SPI–HBT0.5–GL0.5, presents multifunctional properties, including a combination of excellent toughness, tensile strength, conductivity, translucence, recyclability, and excellent thermal stability. Meanwhile, this multifunctional film could be simply degraded in phosphate buffered saline solution and does not cause any pollution to the environment. Attractively, wearable sensors prepared with this particular material (SPI–HBT0.5–GL0.5) displayed excellent biocompatibility, prevented the occurrence of an immune response, and could accurately monitor various types of human joint motions and successfully remain operable after 10,000 cycles. These properties make the developed SPI-based film a great candidate in formulating biobased and multifunctional wearable electronics.

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“…[ 4–6 ] An assessment of the life cycle impact of lignocellulosics considers aspects such as sowing, growing, harvesting, extraction of isolated components, processing, transport, use, and end of life. [ 7 ] Furthermore, there is a pressing societal need to close the loops of material streams to achieve a circular economy.…”

Section: Introductionmentioning

confidence: 99%

“…[4][5][6] An assessment of the life cycle impact of lignocellulosics considers aspects such as sowing, growing, harvesting, extraction of isolated components, processing, transport, use, and end of life. [7] Furthermore, there is a pressing societal need to close the loops of material streams to achieve a circular economy. This review addresses the reconstruction of structural plant components (cellulose, lignin, and hemicelluloses) into materials displaying advanced optical properties.…”

mentioning

confidence: 99%

Plant‐Based Structures as an Opportunity to Engineer Optical Functions in Next‐Generation Light Management

et al. 2021

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This review addresses the reconstruction of structural plant components (cellulose, lignin, and hemicelluloses) into materials displaying advanced optical properties. The strategies to isolate the main building blocks are discussed, and the effects of fibrillation, fibril alignment, densification, self‐assembly, surface‐patterning, and compositing are presented considering their role in engineering optical performance. Then, key elements that enable lignocellulosic to be translated into materials that present optical functionality, such as transparency, haze, reflectance, UV‐blocking, luminescence, and structural colors, are described. Mapping the optical landscape that is accessible from lignocellulosics is shown as an essential step toward their utilization in smart devices. Advanced materials built from sustainable resources, including those obtained from industrial or agricultural side streams, demonstrate enormous promise in optoelectronics due to their potentially lower cost, while meeting or even exceeding current demands in performance. The requirements are summarized for the production and application of plant‐based optically functional materials in different smart material applications and the review is concluded with a perspective about this active field of knowledge.

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Flexible and Green Electronics Manufactured by Origami Folding of Nanosilicate-Reinforced Cellulose Paper

Cited by 24 publications

References 57 publications

Handwritten and Sustainable Electronic Logic Circuits with Fully Printed Paper Transistors

Handwritten and Sustainable Electronic Logic Circuits with Fully Printed Paper Transistors

“Green” Flexible Electronics: Biodegradable and Mechanically Strong Soy Protein-Based Nanocomposite Films for Human Motion Monitoring

Plant‐Based Structures as an Opportunity to Engineer Optical Functions in Next‐Generation Light Management

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