Recent Trends in Electrode and Electrolyte Design for Aluminum Batteries

Rechargeable aluminum‐ion batteries (AIBs) are promising for large‐scale energy storage due to the abundant reserves, low cost, and high capacity of the Al anode. However, the development of AIBs is currently hindered by the usage of AlCl3/1‐ethyl‐3‐methylimidazolium chloride electrolyte, which is expensive, highly corrosive, and extremely air‐sensitive. Herein, a new hydrated eutectic electrolyte (HEE) composed of hydrated aluminum perchlorate and succinonitrile for low‐cost, noncorrosive, and air‐stable AIBs is reported. Crystal water in the hydrated aluminum perchlorate plays a vital role in forming the HEE, in which one H2O and five succinonitrile molecules coordinate with one Al3+ ion. The optimized ratio of Al(ClO4)3·9H2O to succinonitrile is 1:12. When combining with the self‐doped polyaniline cathode, the associated AIB delivers a high discharge capacity of 185 mAh g−1 over 300 cycles; and the charge/discharge mechanism in the HEE is studied experimentally and theoretically. The HEE is nonflammable, air‐stable, and noncorrosive, thus enabling good air tolerance and facile fabrication of AIBs.

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“…[ 6 ] Additionally, the high cost and humidity sensitivity of AlCl 3 /[EMIm]Cl further hamper the commercialization of AIBs. [ 7 ]…”

Section: Introductionmentioning

confidence: 99%

A Low‐Cost and Air‐Stable Rechargeable Aluminum‐Ion Battery

et al. 2022

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“…Therefore, SABs are emerging batteries with great development potential. [44] However, SABs are not stable in traditional aqueous electrolytes and may generate some by-products, such as Al 2 O 3 and H 2 , [45] which seriously affects the cycle life of batteries. Fortunately, the introduction of ionic liquid (IL) electrolytes helps to alleviate the above issues while also improving the performance of SABs.…”

Section: Oems In Sabsmentioning

confidence: 99%

“…In addition, the standard electrode potential ( vs standard hydrogen electrode (SHE)) of Al element is 1.68 V, making SABs relatively safe among metal‐ion batteries. Therefore, SABs are emerging batteries with great development potential [44] . However, SABs are not stable in traditional aqueous electrolytes and may generate some by‐products, such as Al 2 O 3 and H 2 , [45] which seriously affects the cycle life of batteries.…”

Section: Oems In Sabsmentioning

confidence: 99%

Recent Progress on Organic Electrode Materials for Multivalent (Zn, Al, Mg, Ca) Secondary Batteries

Ding

Tian

et al. 2022

Batteries & Supercaps

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Batteries & Supercaps www.batteries-supercaps.org Review doi.org/10.1002/batt.202200160Multivalent secondary batteries (MSBs) have attracted great attention in view of their rich resources, low cost, and high safety. However, its development and application are still plagued by electrode materials. With their renewable and highly adjustable structures, organic electrode materials (OEMs) have several advantages over traditional inorganic electrode materials (IEMs), which has become the current research hotspot of electrode materials for MSBs. In this review, we present the recent developments in OEMs used for secondary batteries, including carbonyl compounds, imine compounds, conductive polymers, covalent organic frameworks, organic cyanides, organosulfur polymers and so on. An overview of the structural characteristics, energy storage mechanism, and electrochemical performance of OEMs in MSBs is given. Furthermore, to reveal the reasons for the high performance of the preponderant organic electrode materials, the relationships between material structures, electrolyte system, and battery properties are discussed in detail. Finally, we hope that this review could provide a fundamental guide to developing and designing high-performance MSBs in the future.

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“…[42][43][44][45][46] Similarly, Ca-ion HSCs have a large theoretical capacity (1337 mAh g −1 , 2073 Ah L −1 ), but Ca-ion deintercalation is hampered by the easily generated passivation layer in the organic electrolyte. [47][48][49][50] The trivalent Al-ion HSC has the highest theoretical capacity (2980 mAh g −1 , 8046 Ah L −1 ), [51][52][53] but a passivation oxide layer is easily formed on the surface, which prevents Al 3+ deintercalation and is frequently accompanied by a side reaction of hydrogen evolution.…”

Section: Introductionmentioning

confidence: 99%

Zinc‐ion hybrid supercapacitors: Design strategies, challenges, and perspectives

Chen

Zhang

Gao

et al. 2022

Carbon Neutralization

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Zinc‐ion hybrid supercapacitors (ZHSCs) may be the most promising energy storage device alternatives for portable and large‐scale electronic devices in the future, as they combine the benefits of both supercapacitors and zinc‐ion batteries. Even though many surprise outcomes have been accomplished with ZHSCs, the creation of suitable cathode materials and electrolytes, as well as the enhancement of zinc anodes, continue to be the most difficult obstacles in the development of high‐performance ZHSCs. The low capacitance of the cathode material, poor stability, and low utilization rate of the zinc anode seriously affect the electrochemical performance and application of ZHSCs. Furthermore, parasitic processes in aqueous electrolytes, such as the hydrogen and oxygen evolution reactions might result in low‐voltage windows and unsatisfied cycling performance of the ZHSCs. This review provides a concise summary of the most recent developments and energy storage mechanisms in ZHSCs. Meanwhile, the cathode material design strategy (structural engineering, hybrid‐composite design, heteroatom doping, and so on), the zinc anode design strategy (zinc foil improvement, zinc‐free metal composites, and so on), and the structure–activity relationship of the electrochemical performance of ZHSCs are discussed. Additionally, a summary of the impact of modifications in electrolyte composition on the electrochemical performance of ZHSCs is provided. Finally, this review also discusses the future development direction of ZHSCs. It is anticipated that this evaluation will serve as a helpful reference for the creation of high‐performance ZHSCs, which will hasten the development of these devices.

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Recent Trends in Electrode and Electrolyte Design for Aluminum Batteries

Cited by 35 publications

References 75 publications

A Low‐Cost and Air‐Stable Rechargeable Aluminum‐Ion Battery

A Low‐Cost and Air‐Stable Rechargeable Aluminum‐Ion Battery

Recent Progress on Organic Electrode Materials for Multivalent (Zn, Al, Mg, Ca) Secondary Batteries

Zinc‐ion hybrid supercapacitors: Design strategies, challenges, and perspectives

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