Toward better electrode/electrolyte interfaces in the ionic-liquid-based rechargeable aluminum batteries

Yang, Hongxun; Wu, Feng; Bai, Ying; Wu, Chuan

doi:10.1016/j.jechem.2019.10.003

Cited by 48 publications

(39 citation statements)

References 50 publications

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“…From the types of organic extractants, ionic liquids constitute a subcategory also of current interest, due to the special characteristics that these reagents present, which somewhat allows them to be referred to as green solvents. These ionic liquids are used in different fields [9][10][11][12] including the removal of metals from aqueous solutions [13][14][15][16].…”

Section: Introductionmentioning

confidence: 99%

Permeation of AuCl4− Across a Liquid Membrane Impregnated with A324H+Cl− Ionic Liquid

López

2020

Metals

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In the system Au(III)-HCl-A324H+Cl−, liquid-liquid extraction experiments were used to define the extraction equilibrium and the corresponding extraction constant; furthermore, the facilitated transport of this precious metal from HCl solutions across a flat-sheet supported liquid membrane was investigated using the same ionic liquid as a carrier, and as a function of different variables: hydrodynamic conditions, concentration of gold(III) (0.01–0.1 g/L), and HCl (0.5–6 M) in the feed phase, and carrier concentration (0.023–0.92 M) in the membrane. An uphill transport equation was derived considering aqueous feed boundary layer diffusion and membrane diffusion as controlling steps. The aqueous diffusional resistance (Δf) and the membrane diffusional resistance (Δm) were estimated from the proposed equation with values of 241 s/cm and 9730 s/cm, respectively. The performance of the present carrier was compared against results yielded by other ionic liquids, and the influence that other metals had on gold(III) transport from both binary or quaternary solutions was also investigated. Gold was finally recovered from receiving solutions as zero valent gold nanoparticles.

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Section: Introductionmentioning

confidence: 99%

Permeation of AuCl4− Across a Liquid Membrane Impregnated with A324H+Cl− Ionic Liquid

López

2020

Metals

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“…Cycle performance and discharge capacity of room-temperature lithium/sulfur cells containing polymer electrolytes and single/binary liquid electrolytes with LiCF 3 SO 3 (1 M) were studied [38]. The cycle property and the cell's first discharge capacity were shown to be largely dependent on the liquid electrolyte content [39].…”

Section: Batteries With Liquid Electrolytementioning

confidence: 99%

“…Rechargeable batteries with non-aqueous electrolytes like ionic liquids have been also reported. These batteries have some problems such as short shelf life, lack of rechargeability, sluggish discharge kinetics, a high self-discharge rate, and the corrosion of aluminum [38]. In the case of the passivation regime, the cell voltage and cell efficiency decreased due to the oxide layer on the Al electrode surface [110].…”

Section: Aluminum-ion Batteriesmentioning

confidence: 99%

The rechargeable aluminum-ion battery with different composite cathodes: A review

Fard

Peighambardoust

Jang

et al. 2020

jcc

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“…The global need for clean and renewable power generation that can respond the best to the rising concerns of fuel consumption has encouraged the use of energy storage systems. The literature has presented different categories of batteries with different characteristics and capacities [1]- [3]. The high energy density and lightweight of Li-ion batteries have allowed them to domination the energy storage market, especially for automotive applications [4].…”

Section: Introductionmentioning

confidence: 99%

Electric and Thermal Model of Li-ion battery pack with cylindrical components

Saqli

Bouchareb

M'Sirdi

et al. 2020

2020 5th International Conference on Renewable Energies for Developing Countries (REDEC)

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In this paper, a Lithium-Ion battery pack is analyzed, modelled and simulated under the Comsol © , Software package. Two cooling methods are investigated in this paper : air-cooling approach and direct liquid cooling approach. This physical oriented model allows to understand the rationale behind the battery pack dynamics and choose an equivalent circuit model which can be used for the State Of Charge (SOC) estimation, the heat prediction and the battery thermal management and control.

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Toward better electrode/electrolyte interfaces in the ionic-liquid-based rechargeable aluminum batteries

Cited by 48 publications

References 50 publications

Permeation of AuCl4− Across a Liquid Membrane Impregnated with A324H+Cl− Ionic Liquid

Permeation of AuCl4− Across a Liquid Membrane Impregnated with A324H+Cl− Ionic Liquid

The rechargeable aluminum-ion battery with different composite cathodes: A review

Electric and Thermal Model of Li-ion battery pack with cylindrical components

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