Highly porous scaffolds for Ru-based microsupercapacitor electrodes using hydrogen bubble templated electrodeposition

Karroubi, Lotfi Benali; Patnaik, Sai Gourang; Assresahegn, Birhanu Desalegn; Bounor, Botayna; Tran, Chau Cam Hoang; Choudhury, Sakeb Hasan; Bourrier, David; Guay, Daniel; Pech, David

doi:10.1016/j.ensm.2022.02.009

Cited by 11 publications

(13 citation statements)

References 30 publications

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“…[ 133 ] The thickness, morphology, and aggregate structure of the electrodeposited film can be precisely controlled by selecting the ED parameters, such as deposition time, deposition temperature, ampere density, and applied voltage. Recent studies have been focused on depositing various electrode materials, that is, metal, [ 134 ] MnO 2 , [ 135 ] RuO 2 , [ 133a,136 ] and Co(OH) 2 , [ 137 ] on the freestanding metal network or ITO substrate to afford FTCEs with high photoelectric performance, electrochemical property, and mechanical flexibility.…”

Section: Fabrication Methods For Ftcesmentioning

confidence: 99%

Fabrication Technologies of Flexible Transparent Electrodes for Supercapacitors: Recent Advances and Perspectives

Lin,

Yang,

Wang

et al. 2023

Adv Materials Technologies

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Flexible transparent portable electronic products provide substantial support for the rapid development of the intelligent era. Flexible transparent supercapacitors (FTSCs) are considered the most promising energy storage devices due to their exceptional electrochemical performance, outstanding mechanical flexibility, and high optical transmittance. However, it is difficult to balance their mechanical flexibility and optical transmittance. The key to reconciling the contradiction is to fabricate flexible transparent conductive electrodes (FTCEs) with excellent mechanical flexibility and optical transmittance by combining the characteristics of manufacturing technologies and electrode materials. In this review, the characteristics of advanced FTCEs manufacturing technologies and their applications in FTSCs are systematically summarized. First, the device structure, working mechanism, and basic performance of FTSCs are briefly introduced. Second, the manufacturing characteristic and principle of different FTCEs preparation technologies are mainly described, including vacuum filtration, coating, deposition, printing, and layer‐by‐layer assembly. Next, the device structure and design principle of multifunctional FTSCs are demonstrated in detail. Finally, the challenges and prospects of applying FTCEs manufacturing technology to construct FTSCs are proposed.

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Section: Fabrication Methods For Ftcesmentioning

confidence: 99%

Fabrication Technologies of Flexible Transparent Electrodes for Supercapacitors: Recent Advances and Perspectives

Lin,

Yang,

Wang

et al. 2023

Adv Materials Technologies

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“…Obviously, the areal capacitance of 14.3 F cm –2 stood out, and the cycling performance was stable for 5,000 charge/discharge cycles without a capacitance loss toward H + charge storage (Figure f,g). This dynamic template method can be also extended to prepare a 3D platinum current collector . Considering the high cost of noble metals, low-cost transition metals are promising candidates.…”

Section: Three-dimensional Macroporous Microelectrodesmentioning

confidence: 99%

“…This dynamic template method can be also extended to prepare a 3D platinum current collector. 127 Considering the high cost of noble metals, low-cost transition metals are promising candidates. The commercially available nickel foam (NF) has been widely used in energy applications owing to its cheap price, abundant microscale pores, and good mechanical strength.…”

Section: Three-dimensional Macroporous Microelectrodesmentioning

confidence: 99%

Advanced Three-Dimensional Microelectrode Architecture Design for High-Performance On-Chip Micro-Supercapacitors

et al. 2022

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The rapid development of miniaturized electronic devices has greatly stimulated the endless pursuit of high-performance on-chip micro-supercapacitors (MSCs) delivering both high energy and power densities. To this end, an advanced three-dimensional (3D) microelectrode architecture design offers enormous opportunities due to high mass loading of active materials, large specific surface areas, fast ion diffusion kinetics, and short electron transport pathways. In this review, we summarize the recent advances in the rational design of 3D architectured microelectrodes including 3D dense microelectrodes, 3D nanoporous microelectrodes, and 3D macroporous microelectrodes. Furthermore, the emergent microfabrication strategies are discussed in detail in terms of charge storage mechanisms and structure− performance correlation for on-chip MSCs. Finally, we conclude with a perspective on future opportunities and challenges in this thriving field.

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“…Micro-supercapacitors (MSCs) emerged as potential energy storage devices complementing microbatteries to power ubiquitous sensor networks needed to foster the development of IoT [3]. Due to the fast surfaceconfined reactions involved in double-layer or pseudocapacitive charging, MSCs show highpower delivery performance through fast charge/discharge along with excellent cycling stability [4][5][6][7][8]. However, these reactions provide low energy density which prevents their largescale adoptability in real device applications.…”

Section: Introductionmentioning

confidence: 99%

Investigation of protic ionic liquid electrolytes for porous RuO2 micro-supercapacitors

Seenath

Pech

Rochefort

2022

Journal of Power Sources

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Highly porous scaffolds for Ru-based microsupercapacitor electrodes using hydrogen bubble templated electrodeposition

Cited by 11 publications

References 30 publications

Fabrication Technologies of Flexible Transparent Electrodes for Supercapacitors: Recent Advances and Perspectives

Fabrication Technologies of Flexible Transparent Electrodes for Supercapacitors: Recent Advances and Perspectives

Advanced Three-Dimensional Microelectrode Architecture Design for High-Performance On-Chip Micro-Supercapacitors

Investigation of protic ionic liquid electrolytes for porous RuO2 micro-supercapacitors

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