All‐Direct‐Ink‐Writing of Artistic Supercapacitors: Toward On‐Demand Embodied Power Sources

Lee, Seong‐Sun; Kim, Se‐Hee; Ahn, Dae Up; Lee, Kwon‐Hyung; Jo, Yejin; Jeong, Sunho; Lee, Sang Young

doi:10.1002/adfm.202202901

Cited by 6 publications

(2 citation statements)

References 57 publications

(64 reference statements)

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“…The highest value achieved was of 15.7 mF cm −2 for 10-stacked electrodes. [367] Additionally, SCs presenting great flexibility were screen printed based on PVA/KOH electrolyte-soaked fabric as a separator, and cost effective MWCNT as electrodes. The proposed sandwiched and all-together SCs revealed areal capacitances of 4.17, and 4.16 mF cm −2 (20 mV s −1 scanning rate), respectively, maintaining their flexibility and high stability even under dynamic bending with high strain rate (20% s −1 ).…”

Section: Energy Storagementioning

confidence: 99%

Advances in Printing and Electronics: From Engagement to Commitment

Martins

Pereira

Lima

et al. 2023

Adv Funct Materials

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In recent years, printed electronics reached enormous popularity as a result of their huge potential to offer unique features that are not attainable through traditional fabrication, namely low‐cost production, multifunctionality, stretchability, sustainability, and flexibility. Being expected a galloping increase in the use of printed technologies in the near future, due to the digitalization efforts associated with the Internet of Things and the 4.0 revolution, it is timely and desirable to discuss the joint features, the interrelations, the complementarities, the interdependency, and the most demanding challenges linked to the relation between printed technologies and electronic materials. In this context, this study offers a broad review of the numerous printing technologies used in the processing of electronics, commonly used substrates, the most effective printed electronic materials, and the key post‐printing treatments such as sintering. Disruptive challenges in various printing techniques, (un)expected future research directions of printed electronics, and imminent application trends are also highlighted, following a critical and subjective perspective.

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Section: Energy Storagementioning

confidence: 99%

Advances in Printing and Electronics: From Engagement to Commitment

Martins

Pereira

Lima

et al. 2023

Adv Funct Materials

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“…Based on this result, the ratio of dodecane/NMP = 90/10 (v/v) was determined as the optimal point for establishing a stable capillary suspension. Meanwhile, the capillary suspension and model suspensions showed that the storage modulus (G′) was higher than the loss modulus (G″) in the low shear stress region, and the opposite trend was observed in the high shear stress region, indicating a typical viscoelastic fluid behavior 29,30 (Figure 1g). The yield stress (τ y ), determined by the intersection of G′ and G″, of the capillary suspension (823.83 Pa) was much higher than those of the NMP-based (2.95 Pa) and dodecane-based (0.62 Pa) model suspensions.…”

mentioning

confidence: 98%

Liquid Metal-Skinned Zn Powder Anodes Enabled by Capillary Suspension

Kang,

Kim,

Ahn

et al. 2024

ACS Energy Lett.

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Biopolymer Composites Material Extrusion and their Applications: A Review

Li,

Yang,

Elias

et al. 2023

Adv Eng Mater

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Advances in additive manufacturing are leading to the emergence of new printable applications, including sensors for healthcare monitoring and bioengineering scaffolds. Research is driven by designing new printable inks including composites that can be extruded and respond to changes in their surroundings and patterning these materials on the microscale. In modern printing techniques, an emerging modified three‐dimensional (3D) printing method: materials extrusion has been utilized for customizable electronics because of its high compatibility with various inks, low cost, and versatility to different levels of complexity. Material extrusion enables not only the printing of 2D and 3D architecture of the electrode structure but also the bioprinting of structures such as conductive scaffolds. In this review, fundamental insights into rational printable ink formulation including colloidal suspensions, gels, polymer melts, composites, printing criteria, processes, and applications toward printable electronics using composites composed of nanomaterials and biopolymers are fully discussed. New manufacturing insights on how to further improve the resolution and simplify the printing process of responsive materials are discussed, which have not been seen in currently published representative reviews. It is envisioned that this review provides high scientific merits to readers working in wearable devices, biological smart materials, and flexible nanoelectronics.

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All‐Direct‐Ink‐Writing of Artistic Supercapacitors: Toward On‐Demand Embodied Power Sources

Cited by 6 publications

References 57 publications

Advances in Printing and Electronics: From Engagement to Commitment

Advances in Printing and Electronics: From Engagement to Commitment

Liquid Metal-Skinned Zn Powder Anodes Enabled by Capillary Suspension

Biopolymer Composites Material Extrusion and their Applications: A Review

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