Initial Electrode Kinetics of Anion Intercalation and De‐intercalation in Nonaqueous <scp>Al‐Graphite</scp> Batteries<sup>†</sup>

Han, Dan; Cao, Mao‐Sheng; Li, Na; She, Dongmei; Song, Wei‐Li; Chen, Haosen; Jiao, Shuqiang; Fang, Daining

doi:10.1002/cjoc.202000389

Cited by 9 publications

(6 citation statements)

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“…The experimental results also confirmed the practical diffusion coefficient of graphite electrode. The results indicate that the value could reach on the order of ∼10 –8 cm 2 s –1 in nonaqueous RABs, which would decrease with progressive AlCl 4 – anion intercalation …”

Section: Thermodynamics and Kinetics Of Rabsmentioning

confidence: 99%

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Nonaqueous Rechargeable Aluminum Batteries: Progresses, Challenges, and Perspectives

et al. 2021

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For significantly increasing the energy densities to satisfy the growing demands, new battery materials and electrochemical chemistry beyond conventional rocking-chair based Li-ion batteries should be developed urgently. Rechargeable aluminum batteries (RABs) with the features of low cost, high safety, easy fabrication, environmental friendliness, and long cycling life have gained increasing attention. Although there are pronounced advantages of utilizing earth-abundant Al metals as negative electrodes for high energy density, such RAB technologies are still in the preliminary stage and considerable efforts will be made to further promote the fundamental and practical issues. For providing a full scope in this review, we summarize the development history of Al batteries and analyze the thermodynamics and electrode kinetics of nonaqueous RABs. The progresses on the cutting-edge of the nonaqueous RABs as well as the advanced characterizations and simulation technologies for understanding the mechanism are discussed. Furthermore, major challenges of the critical battery components and the corresponding feasible strategies toward addressing these issues are proposed, aiming to guide for promoting electrochemical performance (high voltage, high capacity, large rate capability, and long cycling life) and safety of RABs. Finally, the perspectives for the possible future efforts in this field are analyzed to thrust the progresses of the state-of-the-art RABs, with expectation of bridging the gap between laboratory exploration and practical applications.

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Section: Thermodynamics and Kinetics Of Rabsmentioning

confidence: 99%

“…The results indicate that the value could reach on the order of ∼10 −8 cm 2 s −1 in nonaqueous RABs, which would decrease with progressive AlCl 4 − anion intercalation. 125 For 3D diffusion with geometry factor b of 6, the diffusion coefficient can be written as eq 32: 123…”

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Nonaqueous Rechargeable Aluminum Batteries: Progresses, Challenges, and Perspectives

et al. 2021

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“…Han et al. [ 66 ] determined that the selection of appropriate graphite powders could be an essential factor in influencing the electrochemical performance of Al‐graphite cells because the graphite size could fundamentally determine the kinetics of both mass transport in the electrolyte and diffusion ability in the graphitic layers.…”

Section: Recent Progresses Of Positive Materialsmentioning

confidence: 99%

Design Strategies of High‐Performance Positive Materials for Nonaqueous Rechargeable Aluminum Batteries: From Crystal Control to Battery Configuration

Wang

Lei

et al. 2022

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such as high working voltage, large energy density, small volume, lightweight, and environmental friendliness. However, the limited Li and Co resources will increase the LIB cost, and the overcharge and/or overdischarge put it at risk of explosion and combustion, which can restrict its further application. [1,2] From the perspective of a sustainable development strategy, it is imperative to develop a chemical power supply system with low cost, high safety, long cycle life, and high energy density by utilizing elements with richer earth reserves. [3] In recent years, research on aluminumion batteries has provided new insight to solve the abovementioned issues. Compared with traditional secondary batteries, rechargeable aluminum batteries (RABs) possess the advantages of low cost, good safety, large capacity, long cycle life, wide temperature performance, and diverse chemical components and phases, which have promising applications in commercial energy storage systems. [4][5][6][7][8][9] The development of RABs not only helps to solve the problem of excess bulk metal aluminum, [10] but also is of great significance to future energy storage systems. Currently, nonaqueous RABbased ionic liquids, molten salts, quasi-solid and solid electrolytes have attracted substantial attention and have made great progresses. [11][12][13][14][15][16] Compared with advanced commercial LIBs, current nonaqueous RABs are still in their infancy, and their true potential remains to be explored. To realize large-scale application, more efforts have been made, such as clarifying the reaction mechanisms and developing high-performance positive materials. As a series of novel positive materials have achieved significant breakthroughs, nonaqueous RABs have gained more attention. Different from the traditional single ion rocking-chair battery (taking LIBs as a typical representative), nonaqueous RABs have more than two kinds of active species participating in the reaction processes of the positive electrode and negative electrode. In AlCl 3 -based acidic electrolytes, the anions are mainly AlCl 4 − and Al 2 Cl 7 −. With an increase in the AlCl 3 molar ratio, Al 2 Cl 7 −The ORCID identification number(s) for the author(s) of this article can be found under https://doi.org/10.1002/smll.202201362.

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“…À intercalation into the graphite matrix. [10,11] Han et al [12] compared the performance of four different graphite materials and concluded that graphite size affects the reversibility and kinetics of AlCl 4 À diffusion into graphite electrodes during intercalation/deintercalation processes. They claimed that graphite morphology influences the trapping, diffusion coefficient and mass transfer kinetics of AlCl 4 À intercalation/deintercalation into/from graphite.…”

Section: Introductionmentioning

confidence: 99%

Impact of Aluminium Electrode Potential during Charging on Aluminium‐Ion Battery Performance with TEA‐AlCl₃ Electrolyte

Mukundan

Eckert

Drillet

2023

Batteries & Supercaps

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In aluminium (Al) symmetric cell, potentials during Al deposition on an Al foil at 1 mA cm−2 were 60–70 mV higher in TEA‐AlCl3 electrolyte compared to those measured with EMIMCl‐AlCl3 reference. Because of higher electrochemical stability of TEA‐AlCl3 solution, cut‐off voltage of charging step in AIB full‐cell was set to 2.45 V compared to 2.40 V for the reference cell. During long‐term cycling at 1 A g−1, the specific capacity of the AIB cell employing TEA‐AlCl3 increased from 60 to 94 mAh g−1 (57 %) after 1000 cycles while that of cell with EMIMCl‐AlCl3 was quite constant at about 60 mAh g−1. This behaviour was explained by continuous decreasing in Al electrode potential at End‐of‐Charge state (EOC) during deposition reaction (charging step) in TEA‐AlCl3 allowing an increase in graphite electrode potential and consequently in AIB cell capacity over the whole experiment. This increase in capacity was accompanied by a raise of defect sites in graphite material.

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Initial Electrode Kinetics of Anion Intercalation and De‐intercalation in Nonaqueous Al‐Graphite Batteries^†

Cited by 9 publications

References 36 publications

Nonaqueous Rechargeable Aluminum Batteries: Progresses, Challenges, and Perspectives

Nonaqueous Rechargeable Aluminum Batteries: Progresses, Challenges, and Perspectives

Design Strategies of High‐Performance Positive Materials for Nonaqueous Rechargeable Aluminum Batteries: From Crystal Control to Battery Configuration

Impact of Aluminium Electrode Potential during Charging on Aluminium‐Ion Battery Performance with TEA‐AlCl₃ Electrolyte

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Initial Electrode Kinetics of Anion Intercalation and De‐intercalation in Nonaqueous Al‐Graphite Batteries†

Cited by 9 publications

References 36 publications

Nonaqueous Rechargeable Aluminum Batteries: Progresses, Challenges, and Perspectives

Nonaqueous Rechargeable Aluminum Batteries: Progresses, Challenges, and Perspectives

Design Strategies of High‐Performance Positive Materials for Nonaqueous Rechargeable Aluminum Batteries: From Crystal Control to Battery Configuration

Impact of Aluminium Electrode Potential during Charging on Aluminium‐Ion Battery Performance with TEA‐AlCl3 Electrolyte

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Initial Electrode Kinetics of Anion Intercalation and De‐intercalation in Nonaqueous Al‐Graphite Batteries^†

Impact of Aluminium Electrode Potential during Charging on Aluminium‐Ion Battery Performance with TEA‐AlCl₃ Electrolyte