Aluminum Foil Anodes for Li-Ion Rechargeable Batteries: the Role of Li Solubility within β-LiAl

Zheng, Tianye; Kramer, Dominik; Mönig, Reiner; Boles, Steven T.

doi:10.1021/acssuschemeng.1c07242

Cited by 32 publications

(49 citation statements)

References 33 publications

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“…After holding the Li/Al half-cell at 0.40 V versus Li/Li + for an hour, following the strategy described by Geronov et al, the potential is adjusted to a level as low as 0.01 V (V 2 ) to form a great amount of β-LiAl nuclei on the Al surface within only 15 min (Figure S1). When the potential jumps back to a moderate level at 0.15 V versus Li/Li + (V 3 ), the subsequent phase transformation will mostly take place at the positions where the β-LiAl nuclei already exist, resulting in a layer of β-LiAl that homogeneously covers the Al foil surface with a targeted thickness based on anticipated device capacity …”

Section: Resultsmentioning

confidence: 99%

“…90% capacity retention. Since the cycled capacity is limited by the ACF, the (de-)saturation of the β-LiAl layer should prevail instead of the α/β/α phase transformations . Compared to the poor cycling lives of Al anodes reported by others, our device takes advantage of the solubility range of β-LiAl that circumvents the intrinsic problems arising from the phase transformations, such as mechanical strain and formation of nanopores .…”

Section: Resultsmentioning

confidence: 99%

“…When the potential jumps back to a moderate level at 0.15 V versus Li/Li + (V 3 ), the subsequent phase transformation will mostly take place at the positions where the β-LiAl nuclei already exist, resulting in a layer of β-LiAl that homogeneously covers the Al foil surface with a targeted thickness based on anticipated device capacity. 14 …”

Section: Resultsmentioning

confidence: 99%

“…Since the cycled capacity is limited by the ACF, the (de-)saturation of the β-LiAl layer should prevail instead of the α/β/α phase transformations. 14 Compared to the poor cycling lives of Al anodes reported by others, our device takes advantage of the solubility range of β-LiAl that circumvents the intrinsic problems arising from the phase transformations, such as mechanical strain 17 and formation of nanopores. 18 The device delivers ∼1.6 mWh cm –2 at an areal power of ∼5.6 mW cm –2 (single-side), or a gravitational energy of ∼25.6 mWh g –1 at a gravitational power of ∼88.3 mW g –1 , normalized to the total mass of both Al and ACF.…”

Section: Resultsmentioning

confidence: 99%

See 3 more Smart Citations

Simplifying Electrode Design for Lithium-Ion Rechargeable Cells

Zheng

Boles

2022

ACS Omega

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In the race to increase lithium-ion cell manufacturing, labor and energy costs quickly ascend to become chief concerns for building new facilities, as conventional electrode designs need significant resources during fabrication. Complicating this issue is an empirical trade-off between environmental friendliness and ethical sourcing. To circumvent this paradox, modified cell designs that employ foils and textiles can significantly change manufacturing considerations if their simple construction can be matched with competitive performance. In this work, we demonstrate one possible cell design for a lithium-ion device that utilizes a fabric and a foil for the cathode and the anode, respectively. For the anode, a prelithiated aluminum foil is chosen, as the room-temperature solubility range of the LiAl phase is well-suited to uptake and release lithium, all while reducing energy or cost-intensive production steps. The cathode is composed of activated carbon fiber textiles, which offer a scalable path to realize sustainability. With such benefits, this device design can potentially change the calculus for the mass production of energy storage devices.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

See 2 more Smart Citations

Simplifying Electrode Design for Lithium-Ion Rechargeable Cells

Zheng

Boles

2022

ACS Omega

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“…15 Like most alloy anode materials, these problems are intrinsically coupled to the host element/matrix, and thus challenging to resolve. Alternatively, smart strategies to circumvent the huge mechanical stress 16 or restrict the α/β phase transformation (i.e., limited to the solubility range of β-LiAl) 17 hold promise for enabling room temperature Al anodes for LIBs.…”

mentioning

confidence: 99%

Unlocking the High Capacity and Stability of Aluminum Anodes for Lithium-Ion Batteries through Strategic Thermal Control

Zheng

Zhang

Jin

et al. 2022

Preprint

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Lithium-ion batteries with aluminum anodes had appeared to resolve critical dendrite issues of lithium metal cells in the 1970s. However, the poor cycling attributed to aluminum anodes would lead to their obsolescence. In this work, we demonstrate how strategic thermal control circumvents the problematic α/β phase transformations. The electrochemical formation of Li3Al2 and Li2-xAl, which necessitates temperatures slightly above ambient, are the key enablers for high capacity and stable cycling. While delivering a competitive capacity level (ca. 1 Ah kg-1-Al), those higher-order phases exhibit significantly improved cycling behaviors, from a few cycles to one hundred cycles with ca. 67% capacity retention. Since modern battery charging is likely to occur above ambient due to ohmic heating, the thermal conditions explored here are likely to be realized in a variety of applications. Importantly, this elevated temperature is not necessary for aluminum anode delithiation, thus creating additional synergies with many practical scenarios.

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Highly Fluorinated Interphase Enables the Exceptional Stability of Monolithic Al Foil Anode for Li‐Ion Batteries

Tan,

Zhang,

Liu

et al. 2024

Adv Funct Materials

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Directly using aluminum (Al) foil as anode material offers a streamlined manufacturing process by eliminating the need for conductive additives, binders, and casting procedures. Nonetheless, monolithic Al foil anodes often suffer from mechanical failure and poor cyclability, posing challenges for practical adoption. In this study, a high‐concentration ether‐based electrolyte is employed to boost the durability of the Al foil anode. In contrast to traditional low‐concentration electrolytes, the use of 5 m lithium bis(fluorosulfonyl)imide in 1,2‐dimethoxyethane promotes the priority decomposition of anions, leading to the creation of a fluoride‐rich solid electrolyte interphase (SEI) layer with exceptional structural modulus and high ion conductivity. These outcomes, coupled with Al's superior compatibility in the chosen electrolyte, enable a record‐breaking cycle life of up to 400 cycles for Li//Al half‐cells, when operated at a high areal capacity of 1 mAh cm−2. In full‐cell configurations, an outstanding capacity retention is also observed, with 96.9% after 150 cycles even under practical conditions involving a 40 µm thin Al foil and a 7.4 mg cm−2 LiFePO4 cathode. These results not only mark the pioneering use of high‐concentration ether‐based electrolyte systems in Al foil anodes but also showcase the high potential for developing low‐cost and high‐energy Al foil‐based LIBs.

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Aluminum Foil Anodes for Li-Ion Rechargeable Batteries: the Role of Li Solubility within β-LiAl

Cited by 32 publications

References 33 publications

Simplifying Electrode Design for Lithium-Ion Rechargeable Cells

Simplifying Electrode Design for Lithium-Ion Rechargeable Cells

Unlocking the High Capacity and Stability of Aluminum Anodes for Lithium-Ion Batteries through Strategic Thermal Control

Highly Fluorinated Interphase Enables the Exceptional Stability of Monolithic Al Foil Anode for Li‐Ion Batteries

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