Recent Advances in Rechargeable Aluminum-Ion Batteries and Considerations for Their Future Progress

Zhang, Kaiqiang; Kirlikovali, Kent O.; Suh, Jun Min; Choi, Ji‐Won; Jang, Ho Won; Varma, Rajender S.; Farha, Omar K.; Shokouhimehr, Mohammadreza

doi:10.1021/acsaem.0c00957

Cited by 68 publications

(45 citation statements)

References 195 publications

(266 reference statements)

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“…The saturation limit reached a value of 5 M. The acceptable catalytic activity, simplied procurement, and stability of the Cu 2 O/PPy composite indicate that it is a very good electrocatalyst for the oxidation of ethanol. [128][129][130][131]…”

Section: Energy Storage and Conversionmentioning

confidence: 99%

Recent developments in conducting polymers: applications for electrochemistry

et al. 2020

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Section: Energy Storage and Conversionmentioning

confidence: 99%

Recent developments in conducting polymers: applications for electrochemistry

et al. 2020

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“…In a search for inexpensive, large‐scale stationary storage of electricity, non‐aqueous Al‐graphite dual‐ion batteries (AGDIBs) have attracted recently much attention due to the high natural abundances of their primary constituents, the long cycle life of up to a quarter of a million cycles, the high energy efficiency of 80–90 % and facile manufacturing [1–8] . While recent research efforts on AGDIBs have been mainly focused on the judicious selection of carbonaceous cathode materials, leading to the most notable advances in the performance of AGDIBs, [9–27] the major challenge with such batteries is that they lag behind Li‐ion batteries in theoretical cell‐level energy density.…”

Section: Figurementioning

confidence: 99%

AlCl₃‐Saturated Ionic Liquid Anolyte with an Excess of AlCl₃ for Al–Graphite Dual‐Ion Batteries

Wang

Kovalenko

Kravchyk

2021

Batteries & Supercaps

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Al–graphite dual‐ion batteries (AGDIBs) represent a compelling battery concept for large‐scale stationary storage of electricity in view of their safety, low cost, long cycling life, and high energy efficiency (80–90 %). However, at present, the deployment of AGDIBs is intrinsically limited by their low cell‐level energy density as a result of the non‐rocking‐chair operation principle and, consequently, the need for large quantities of acidic chloroaluminate ionic liquid (IL) anolytes as a reservoir of Al2Cl7− ions required for AGDIB operation. Thus far, AGDIBs have commonly employed IL anolytes with moderate acidity (AlCl3/Lewis base molar ratio of 1.3), which corresponds to charge‐storage anolyte capacity of ca. 19 mAh g−1, eventually resulting in low cell‐level energy densities of 20–30 Wh kg−1. In this work, we present an AGDIB utilizing an AlCl3‐saturated IL anolyte, containing an excess of AlCl3 powder for maintaining constant acidity during operation, leading to a theoretical capacity of 52 mAh g−1. The resultant AGDIB possesses an energy density of 59.1 Wh kg−1, along with a high energy efficiency of 85 % and an average discharge voltage of 1.71 V.

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“…Conventional secondary batteries based on lithium, [ 39 ] sodium, [ 40 ] aluminum, [ 41 ] magnesium, [ 42 ] or zinc‐ion chemistries [ 43 ] are usually composed of chemically stable carbon nanomaterials/metals/metal oxides as electrodes and current collectors, nondegradable polymers as separators, organic liquids as electrolytes, and the full cell is protected by a metallic casing for high safety assurance. In this context, the potential environmental and human health effects of secondary batteries were studied using life cycle impact assessment, concluding that such batteries can be classified as hazardous due to their excessive contents of lead, cobalt, nickel, copper, chromium, thallium, and flammable electrolytes.…”

Section: Introductionmentioning

confidence: 99%

Degradation Behavior, Biocompatibility, Electrochemical Performance, and Circularity Potential of Transient Batteries

et al. 2021

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Transient technology seeks the development of materials, devices, or systems that undergo controlled degradation processes after a stable operation period, leaving behind harmless residues. To enable externally powered fully transient devices operating for longer periods compared to passive devices, transient batteries are needed. Albeit transient batteries are initially intended for biomedical applications, they represent an effective solution to circumvent the current contaminant leakage into the environment. Transient technology enables a more efficient recycling as it enhances material retrieval rates, limiting both human and environmental exposures to the hazardous pollutants present in conventional batteries. Little efforts are focused to catalog and understand the degradation characteristics of transient batteries. As the energy field is a property‐driven science, not only electrochemical performance but also their degradation behavior plays a pivotal role in defining the specific end‐use applications. The state‐of‐the‐art transient batteries are critically reviewed with special emphasis on the degradation mechanisms, transiency time, and biocompatibility of the released degradation products. The potential of transient batteries to change the current paradigm that considers batteries as harmful waste is highlighted. Overall, transient batteries are ready for takeoff and hold a promising future to be a frontrunner in the uptake of circular economy concepts.

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Recent Advances in Rechargeable Aluminum-Ion Batteries and Considerations for Their Future Progress

Cited by 68 publications

References 195 publications

Recent developments in conducting polymers: applications for electrochemistry

Recent developments in conducting polymers: applications for electrochemistry

AlCl₃‐Saturated Ionic Liquid Anolyte with an Excess of AlCl₃ for Al–Graphite Dual‐Ion Batteries

Degradation Behavior, Biocompatibility, Electrochemical Performance, and Circularity Potential of Transient Batteries

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Recent Advances in Rechargeable Aluminum-Ion Batteries and Considerations for Their Future Progress

Cited by 68 publications

References 195 publications

Recent developments in conducting polymers: applications for electrochemistry

Recent developments in conducting polymers: applications for electrochemistry

AlCl3‐Saturated Ionic Liquid Anolyte with an Excess of AlCl3 for Al–Graphite Dual‐Ion Batteries

Degradation Behavior, Biocompatibility, Electrochemical Performance, and Circularity Potential of Transient Batteries

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AlCl₃‐Saturated Ionic Liquid Anolyte with an Excess of AlCl₃ for Al–Graphite Dual‐Ion Batteries