Locally Concentrated Deep Eutectic Liquids Electrolytes for Low‐Polarization Aluminum Metal Batteries

Xu, Cheng; Diemant, Thomas; Liu, Xu; Passerini, Stefano

doi:10.1002/adma.202400263

Advanced Materials

2024

DOI: 10.1002/adma.202400263

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Locally Concentrated Deep Eutectic Liquids Electrolytes for Low‐Polarization Aluminum Metal Batteries

Cheng Xu,

Thomas Diemant,

Xu Liu

et al.

Abstract: Low‐cost and nontoxic deep eutectic liquid electrolytes (DELEs), such as [AlCl3]1.3[Urea] (AU), are promising for rechargeable non‐aqueous aluminum metal batteries (AMBs). However, their high viscosity and sluggish ion transport at room temperature lead to high cell polarization and low specific capacity, limiting their practical application. Herein, non‐solvating 1,2‐difluorobenzene (dFBn) is proposed as a co‐solvent of DELEs using AU as model to construct a locally concentrated deep eutectic liquid electroly… Show more

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Cited by 8 publications

References 70 publications

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Optimized Electrode/Electrolyte Interface Engineering for Dendrite‐Free Al Anode and Self‐Activated Graphite Cathode

Xie,

Meng,

Liu

et al. 2024

Adv Funct Materials

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Rechargeable aluminum batteries (RABs) have garnered attention owing to their impressive theoretical capacity, outstanding safety features, and abundant Al reserves, thereby positioning them as a potential alternative and supplement to fixed energy storage. Nonetheless, RABs still suffer from issues, such as poor anode stability stemming from the corrosivity of the chloral aluminate ionic liquid electrolyte (ILs) and subpar wettability of the cathode. To address these issues, the proposed electrolyte interfacial engineering involves the nonionic surfactant (F127) as an interfacial optimizer in ILs, simultaneously modulating the anode–electrolyte and cathode–electrolyte interfaces. Systematic experiments and theoretical analyses validate that F127 preferentially adsorbs on the electrode surface, forming a dense and uniform adsorption layer. The F127 layer can effectively mitigate the corrosion of ILs on the Al anode and regulate the current density to achieve uniform Al deposition. Furthermore, F127 enhances the wettability between the cathode and ILs, preventing the collapse of the graphite structure and enhancing the active material's utilization. The Al//FG full battery assembled with F127 modifying ILs (F127‐0.5) is able to retain a specific capacity of 104.9 mAh g−1 after 1600 cycles, which is higher than ILs (69.0 mAh g−1). This electrolyte interface modification strategy holds considerable practical significance for achieving long‐lifespan and high‐capacity RABs.

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Optimized Electrode/Electrolyte Interface Engineering for Dendrite‐Free Al Anode and Self‐Activated Graphite Cathode

Xie,

Meng,

Liu

et al. 2024

Adv Funct Materials

View full text Add to dashboard Cite

show abstract

d‐Orbital Induced Electronic Structure Reconfiguration toward Manipulating Electron Transfer Pathways of Metallo‐Porphyrin for Enhanced AlCl₂⁺ Storage

Jiao,

Han,

et al. 2024

Advanced Materials

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The positive electrodes of non‐aqueous aluminum ion batteries (AIBs) frequently encounter significant issues, for instance, low capacity in graphite (mechanism: anion de/intercalation and large electrode deformation induced) and poor stability in inorganic positive electrodes (mechanism: multi‐electron redox reaction and dissolution of active materials induced). Here, metallo‐porphyrin compounds (employed Fe2+, Co2+, Ni2+, Cu2+, and Zn2+ as the ion centers) are introduced to effectively enhance both the cycling stability and reversible capacity due to the formation of stable conjugated metal‐organic coordination and presence of axially coordinated active sites, respectively. With the regulation of electronic energy levels, the d‐orbitals in the redox reactions and electron transfer pathways can be rearranged. The 5,10,15,20‐tetraphenyl‐21H,23H‐porphine nickle(II) (NiTPP) presents the highest specific capacity (177.1 mAh g−1), with an increment of 32.1% and 77.1% in comparison with the capacities of H2TPP and graphite, respectively, which offers a new route for developing high‐capacity positive electrodes for stable AIBs.

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Boosting the Structural and Electrochemical Stability of Chloride‐Ion‐Conducting Perovskite Solid Electrolytes by Alkali Ion Doping

Xia,

Li,

Xue

et al. 2024

Advanced Materials

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The use of chloride‐based solid electrolytes derived from Lewis acid‒base reactions enables the construction of various new rechargeable batteries, such as chloride ion batteries (CIBs). However, a critical problem with these electrolytes is their poor stability under low‐temperature, moist, or electrochemical conditions, which can lead to deterioration of the phase structure and a loss of ion conduction. Herein, the robust cubic structure of tin‐based perovskite chloride—a chloride ion conductor—is achieved by alkali ion doping at the tin site via direct mechanical milling. The as‐prepared cubic CsSn0.925Na0.075Cl2.925 (CSNC) electrolyte exhibits outstanding structural stability over a broad temperature range of 213−473 K or under a high relative humidity of up to 90%, at which the typical chloride electrolytes previously reported deteriorate because of moisture. Importantly, mild annealing can modify the microstructure of the CSNC, resulting in a two fold increase in ionic conductivity and an increase in electrochemical stability, which is superior to those of other chloride electrolytes reported in previous studies. The effective chloride‐ion transfer and wide electrochemical window of the CSNC are further demonstrated in different solid‐state CIBs.

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Locally Concentrated Deep Eutectic Liquids Electrolytes for Low‐Polarization Aluminum Metal Batteries

Cited by 8 publications

References 70 publications

Optimized Electrode/Electrolyte Interface Engineering for Dendrite‐Free Al Anode and Self‐Activated Graphite Cathode

Optimized Electrode/Electrolyte Interface Engineering for Dendrite‐Free Al Anode and Self‐Activated Graphite Cathode

d‐Orbital Induced Electronic Structure Reconfiguration toward Manipulating Electron Transfer Pathways of Metallo‐Porphyrin for Enhanced AlCl₂⁺ Storage

Boosting the Structural and Electrochemical Stability of Chloride‐Ion‐Conducting Perovskite Solid Electrolytes by Alkali Ion Doping

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Locally Concentrated Deep Eutectic Liquids Electrolytes for Low‐Polarization Aluminum Metal Batteries

Cited by 8 publications

References 70 publications

Optimized Electrode/Electrolyte Interface Engineering for Dendrite‐Free Al Anode and Self‐Activated Graphite Cathode

Optimized Electrode/Electrolyte Interface Engineering for Dendrite‐Free Al Anode and Self‐Activated Graphite Cathode

d‐Orbital Induced Electronic Structure Reconfiguration toward Manipulating Electron Transfer Pathways of Metallo‐Porphyrin for Enhanced AlCl2+ Storage

Boosting the Structural and Electrochemical Stability of Chloride‐Ion‐Conducting Perovskite Solid Electrolytes by Alkali Ion Doping

Contact Info

Product

Resources

About

d‐Orbital Induced Electronic Structure Reconfiguration toward Manipulating Electron Transfer Pathways of Metallo‐Porphyrin for Enhanced AlCl₂⁺ Storage