Ragone Plots for Electrochemical Double‐Layer Capacitors

Vicentini, Rafael; Aguiar, João Pedro; Beraldo, Renato; Venâncio, Raissa; Rufino, Fernando César; Silva, Leonardo M. Da; Zanin, Hudson

doi:10.1002/batt.202100093

Cited by 44 publications

(33 citation statements)

References 270 publications

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“…According to SC Ragone plots, both HAC-1 and HAC-3 are located more toward the upper, right region in the plot than MPC and HC, therefore, indicating their superior supercapacitor performance (Figure S7b). 50 On the basis of the result from supercapacitor study, we can envisage superior CDI performances of HACs arising from the synergistic effect of hollow nanoarchitecture and high surface area because CDI also exploits EDL formation on the carbon surface (Figure 5a). Consequently, the CDI performance of the carbon samples were measured in a batch-mode recycling system and the best-performing HAC-1 was further analyzed at varying voltages and cycle numbers (Figure 5).…”

Section: Resultsmentioning

confidence: 98%

KOH-Activated Hollow ZIF-8 Derived Porous Carbon: Nanoarchitectured Control for Upgraded Capacitive Deionization and Supercapacitor

Kim

Xin

et al. 2021

ACS Appl. Mater. Interfaces

180

120

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Herein, the synergistic effects of hollow nanoarchitecture and high specific surface area of hollow activated carbons (HACs) are reported with the superior supercapacitor (SC) and capacitive deionization (CDI) performance. The center of zeolite imidazolate framework-8 (ZIF-8) is selectively etched to create a hollow cavity as a macropore, and the resulting hollow ZIF-8 (HZIF-8) is carbonized to obtain hollow carbon (HC). The distribution of nanopores is, subsequently, optimized by KOH activation to create more nanopores and significantly increase specific surface area. Indeed, as-prepared hollow activated carbons (HACs) show significant improvement not only in the maximum specific capacitance and desalination capacity but also capacitance retention and mean desalination rates in SC and CDI, respectively. As a result, it is confirmed that well-designed nanoarchitecture and porosity are required to allow efficient diffusion and maximum electrosorption of electrolyte ions.

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Section: Resultsmentioning

confidence: 98%

KOH-Activated Hollow ZIF-8 Derived Porous Carbon: Nanoarchitectured Control for Upgraded Capacitive Deionization and Supercapacitor

Kim

Xin

et al. 2021

ACS Appl. Mater. Interfaces

180

120

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“…16,19 The results displayed that CHG consists of 3-4 layers. 16,19 After the XRD data, the FT-IR data in Fig. S3 (ESI †) also supports the synthesis of reduced graphene since the peaks of the FT-IR spectrum for carbonyl with reduced intensity (1545 cm À1 ), O-H stretching with a broad intensity (3414 cm À1 ), and carbon-oxygen single bond vibration (866 cm À1 ), are in agreement with the XRD and Raman data.…”

Section: Materials Advances Papermentioning

confidence: 98%

Coconut-husk derived graphene for supercapacitor applications: comparative analysis of polymer gel and aqueous electrolytes

et al. 2023

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“…Furthermore, parameters as the cycle life, charge/ discharge characteristics, mechanical resistance, durability or degradation against external agents (like water, soaps or ultraviolet radiation) are measured to evaluate the future performance of the energy storage device. 50,70 Currently, there is a lack of high-performance polymeric electrode and electrolyte materials so new studies are emerging. 67,71,72 Polymer composites are very often used in energy storage applications due their high dielectric permittivity and high dielectric breakdown strength.…”

Section: Required Physical Properties On the Polymer Composites For E...mentioning

confidence: 99%

“…Both electric breakdown and dielectric permittivity can be easily measured in a laboratory 68 . Polymer dielectric permittivity 69 can be measured either directly with a DEA machine or by measuring the material capacitance, as shown in Equation ().

ε_{r} goodbreak= \frac{C ∙ d}{ε_{0} ∙ A} .

Last, the power density relation with energy density is shown on Equation ().

P_{m} goodbreak= \frac{U_{e}}{t} .

Furthermore, parameters as the cycle life, charge/discharge characteristics, mechanical resistance, durability or degradation against external agents (like water, soaps or ultraviolet radiation) are measured to evaluate the future performance of the energy storage device 50,70 . Currently, there is a lack of high‐performance polymeric electrode and electrolyte materials so new studies are emerging 67,71,72 …”

Section: Introduction Of Energy Storage Devices and Polymer Composite...mentioning

confidence: 99%

Last developments in polymers for wearable energy storage devices

Lage-Rivera

Ares‐Pernas

Abad

2022

Intl J of Energy Research

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Our modern and technological society requests enhanced energy storage devices to tackle the current necessities. In addition, wearable electronic devices are being demanding because they offer many facilities to the person wearing it. In this manuscript, a historical review is made about the available energy storage devices focusing on super-capacitors and lithium-ion batteries, since they currently are the most present in the industry, and the possible polymeric materials suitable on wearable energy storage devices. Polymers are a suitable option because they not only possess remarkable mechanical resistance, flexibility, long life-times, easy manufacturing techniques and low cost in addition to they can be environmentally friendly, nontoxic, and even biodegradable too. Moreover, the electrical and electrochemical polymer properties can be tunning with suitable fillers giving to versatile conducting polymer composites with a good cost and properties' ratio. Although the advances are promising, there are still many drawbacks that need to be overcome. Future research should focus on improving both the performance of materials and their processability on an industrial scale, where additive manufacturing offers many possibilities. The sustainability of new energy storage devices should not

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Ragone Plots for Electrochemical Double‐Layer Capacitors

Cited by 44 publications

References 270 publications

KOH-Activated Hollow ZIF-8 Derived Porous Carbon: Nanoarchitectured Control for Upgraded Capacitive Deionization and Supercapacitor

KOH-Activated Hollow ZIF-8 Derived Porous Carbon: Nanoarchitectured Control for Upgraded Capacitive Deionization and Supercapacitor

Coconut-husk derived graphene for supercapacitor applications: comparative analysis of polymer gel and aqueous electrolytes

Last developments in polymers for wearable energy storage devices

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