Writing ink-promoted synthesis of electrodes with high energy storage performance: A review

Feng, Yi; Li, Jingqiu; Tian, Ren‐Rong; Yao, Jianfeng

doi:10.1016/j.jechem.2020.05.031

Cited by 12 publications

(12 citation statements)

References 54 publications

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“…In terms of appellation, DCI has many names, including mo (in China), sumi (in Japan), ink, carbon ink, pen ink, fountain pen ink, and Chinese ink. 29,37,46,47 Although there are many brands of DCI (such as Guizhou Boss, 26,27,[31][32][33][34] Shanghai Hero, 48 and Tianjin Ostrich 49 ), their main components are basically the same, including carbon black nanoparticles, deionized water, surfactants, and anti-sedimentation agents. There are certain differences in the prices of DCI with different brands and types.…”

Section: Characteristics Of DCImentioning

confidence: 99%

Amorphous carbon material of daily carbon ink: emerging applications in pressure, strain, and humidity sensors

et al. 2023

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Section: Characteristics Of DCImentioning

confidence: 99%

Amorphous carbon material of daily carbon ink: emerging applications in pressure, strain, and humidity sensors

et al. 2023

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“…In the past few years, multiple 3D printing techniques have been used to manufacture energy storage devices, including inkjet printing [11,19], direct ink writing [20,21], binder jet method [22], fused deposition modeling process [23], stereolithography or optical fabrication or photo-solidification or resin printing [24], and metal 3D printing [26]. A technical comparison of the most selected 3D printing techniques for the fabrication of EES devices has been provided in Table 1.…”

Section: D Printed Electrodes and Their Propertiesmentioning

confidence: 99%

Advances in 3D Printing for Electrochemical Energy Storage Systems

Menon

Khan²,

Balakrishnan

et al. 2021

J. Mater. Sci. Technol. Res.

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In the current scenario, energy generation is relied on the portable gadgets with more efficiency paving a way for new versatile and smart techniques for device fabrication. 3D printing is one of the most adaptable fabrication techniques based on designed architecture. The fabrication of 3D printed energy storage devices minimizes the manual labor enhancing the perfection of fabrication and reducing the risk of hazards. The perfection in fabrication technique enhances the performance of the device. The idea has been built upon by industry as well as academic research to print a variety of battery components such as cathode, anode, separator, etc. The main attraction of 3D printing is its cost-efficiency. There are tremendous savings in not having to manufacture battery cells separately and then assemble them into modules. This review highlights recent and important advances made in 3D printing of energy storage devices. The present review explains the common 3D printing techniques that have been used for the printing of electrode materials, separators, battery casings, etc. Also highlights the challenges present in the technique during the energy storage device fabrication in order to overcome the same to develop the process of 3D printing of the batteries to have comparable performance to, or even better performance than, conventional batteries.

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“…[1,5] One of the main driving forces for developing flexible and low-cost electronic devices is the fabrication of conductive ink. [6,7] To fabricate electronic devices and sensors, conductive ink could be facilely printed on sensitive and flexible substrates such as plastic, clothes, polymeric surfaces, and papers. [8][9][10][11] It is necessary to find appropriate ink formulations that can be processed by screen or inkjet printing to maintain high mechanical and electrical performance.…”

Section: Introductionmentioning

confidence: 99%

“…The flexible and low‐cost electronic devices have attracted extensive attention from scientists and governments worldwide for innovative and future applications such as sensors, electronic displays, smart clothing, solar cells, and field‐effect transistors [1,5] . One of the main driving forces for developing flexible and low‐cost electronic devices is the fabrication of conductive ink [6,7] . To fabricate electronic devices and sensors, conductive ink could be facilely printed on sensitive and flexible substrates such as plastic, clothes, polymeric surfaces, and papers [8–11] .…”

Section: Introductionmentioning

confidence: 99%

Room Temperature‐Sintering Conductive Ink Fabricated from Oleic‐Modified Graphene for the Flexible Electronic Devices

Bui²,

Dinh

et al. 2022

ChemistrySelect

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Graphene, a novel 2D nanomaterial, has been intensively studied and utilized in many fields of applications. Graphenebased conductive ink has attracted many scientific researchers due to its flexibility, durability, and, most importantly, high electrical conductivity. However, the low dispensability and high curing temperature have hindered the use of graphene ink in many practical applications. In this work, graphene nanoplatelets (GNPs) were modified with oleic acid to improve dispensability. Then, the modified GNPs were employed as a major component in the conductive ink's formulation. The effects of the oleic acid, binder, and GNPs contents on the conductivity of the prepared ink were studied. The results showed that at the ink's formulation of 0.75 % binder and 6 % GNPs (modified with 2.5 % oleic acid), the lowest resistance with the value of 22 Ω.cm and sheet resistance of 7.56 Ω cm 2 was obtained. Remarkably, the high conductivity of the modified conductive ink on the substrate could also be observed after curing at room temperature, which is advantageous for practical application. The viscosity of the resultant conductive ink could also be adjusted by changing the amount of solvent in the ink's formulation for application of the ink in the pen, painting, or inkjet printing.

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Writing ink-promoted synthesis of electrodes with high energy storage performance: A review

Cited by 12 publications

References 54 publications

Amorphous carbon material of daily carbon ink: emerging applications in pressure, strain, and humidity sensors

Amorphous carbon material of daily carbon ink: emerging applications in pressure, strain, and humidity sensors

Advances in 3D Printing for Electrochemical Energy Storage Systems

Room Temperature‐Sintering Conductive Ink Fabricated from Oleic‐Modified Graphene for the Flexible Electronic Devices

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