Scalable Dry Processing of Binder-Free Lithium-Ion Battery Electrodes Enabled by Holey Graphene

Kirsch, Dylan; Lacey, Steven D.; Kuang, Yudi; Pastel, Glenn; Hu, Liangbing; Connell, John W.; Lin, Yi; Hu, Liangbing

doi:10.1021/acsaem.9b00066

Cited by 63 publications

(54 citation statements)

References 30 publications

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“…To address this issue, pore engineering has been a strategy adopted by various research groups toward improving the charge transfer kinetics of stacked graphene structures . Most recently, Duan and coworkers reported a 3D holey‐graphene (HGF)/niobia (Nb 2 O 5 ) composite electrode with a hierarchically porous structure .…”

Section: Integrated Electrode and Current Collectormentioning

confidence: 99%

Thick Electrode Batteries: Principles, Opportunities, and Challenges

Kuang

Chen

Kirsch

et al. 2019

Advanced Energy Materials

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491

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Recent reviews on LBs have provided a good overview of the developments of high energy density LBs based on diverse battery chemistries. [3][4][5][6] It is believed that the energy density of current LBs can be improved up to 300-350 Wh kg −1 in a short time by using high-nickel (Ni) content cathodes, silicon (Si) dominant anodes, and higher voltage electrolytes, but further progress is needed to achieve an acceptable lifetime for practical application. [7] In regards to long term goals, continued research and development (R&D) of next-generation LBs is necessary to meet the Battery500 Project target of a cell-level specific energy of 500 Wh kg −1 , [8] which necessitates a combination of both innovative battery chemistries (such as lithium (Li)-sulfur (S), Li-O 2 , Li-CO 2 , and so on), and cell configurations (improved active material ratio and cell integration). [9] However, the majority of current research efforts are dedicated to the R&D of battery materials while battery configurational design is relatively overlooked. Interestingly, with the progress in the development of water-in-salt electrolyte and the corresponding battery chemistry, aqueous LIBs are also possible to meet the Battery 500 Project target. A representative work is the aqueous LIBs that has been recently reported by Yang et al. which achieves a stable operation potential of 4.2 V and energy density of 460 Wh kg −1 . [10] It is great progress but worthy noting that the energy density calculation is based on the mass of anode and cathode. When the mass of the electrolyte is included, the full-cell energy density is dropped to 304 Wh kg −1 , revealing the important role of battery configurational design.Structural engineering provides a feasible and universal way to further improve the energy density of LBs without changing the fundamental battery chemistries. Since the battery's energy only comes from the electrically active materials in the electrodes, the core principle for the novel structural design of batteries is to minimize the ratio of inactive components while maintaining or improving battery performance per mass or volume of active material. Common strategies include the optimization of battery packaging with thinner, more robust materials, the reduction of electrode porosity with a higher packing density and increased electrolyte uptake, and the utilization of thick electrodes. The first is relatively hard to improve in a short time and would require a breakthrough in battery packaging materials with carefully evaluated cost and safety parameters. As for the reduction of electrolyte, it is also difficult toThe ever-growing portable electronics and electric vehicle markets heavily influence the technological revolution of lithium batteries (LBs) toward higher energy densities for longer standby times or driving range. Thick electrode designs can substantially improve the electrode active material loading by minimizing the inactive component ratio at the device level, providing a great platform for enhancing the overall energy densi...

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Section: Integrated Electrode and Current Collectormentioning

confidence: 99%

Thick Electrode Batteries: Principles, Opportunities, and Challenges

Kuang

Chen

Kirsch

et al. 2019

Advanced Energy Materials

Self Cite

491

413

View full text Add to dashboard Cite

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“…Another promising technology proposed by Kirsch et al [ 278 ] is dry processing method in order to make binder‐free nanostructured electrodes into large‐scale production. This method is enabled by a nanoporous carbon allotrope (i.e., holey graphene) acting as the compressible and conductive matrix to accommodate incompressible electrode active materials.…”

Section: Remaining Challenges For Binder‐free Nanostructured Electrodesmentioning

confidence: 99%

“…Then, the mixture is cold pressed into a self‐supported composite which is directly used as a binder‐free electrode in LIBs. Inspired by this dry processing approach, Kirsch et al [ 278 ] come up with a dubbed dry roll‐to‐roll manufacturing process from an industrial processing perspective. This version of the proposed dry processing technique is advantageous in terms of its universality and scalability.…”

Section: Remaining Challenges For Binder‐free Nanostructured Electrodesmentioning

confidence: 99%

Advanced Matrixes for Binder‐Free Nanostructured Electrodes in Lithium‐Ion Batteries

et al. 2020

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Commercial lithium‐ion batteries (LIBs), limited by their insufficient reversible capacity, short cyclability, and high cost, are facing ever‐growing requirements for further increases in power capability, energy density, lifespan, and flexibility. The presence of insulating and electrochemically inactive binders in commercial LIB electrodes causes uneven active material distribution and poor contact of these materials with substrates, reducing battery performance. Thus, nanostructured electrodes with binder‐free designs are developed and have numerous advantages including large surface area, robust adhesion to substrates, high areal/specific capacity, fast electron/ion transfer, and free space for alleviating volume expansion, leading to superior battery performance. Herein, recent progress on different kinds of supporting matrixes including metals, carbonaceous materials, and polymers as well as other substrates for binder‐free nanostructured electrodes in LIBs are summarized systematically. Furthermore, the potential applications of these binder‐free nanostructured electrodes in practical full‐cell‐configuration LIBs, in particular fully flexible/stretchable LIBs, are outlined in detail. Finally, the future opportunities and challenges for such full‐cell LIBs based on binder‐free nanostructured electrodes are discussed.

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“…Carbon materials such as graphite, graphene, and carbon nanober/nanotube oen serve as the current collector to bear active material for avoiding the use of binders. [19][20][21] Another effective solution is to deposit the active material directly on the current collector by electrochemical deposition or chemical deposition, and then to form an integrated electrode without binder. [22][23][24] In contrast, as a common preparation process for polycrystalline thin-lm, closed-space sublimation (CCS) method has the characteristics of simple method, short time, and low cost.…”

Section: Introductionmentioning

confidence: 99%

A novel and fast method to prepare a Cu-supported α-Sb₂S₃@CuSbS₂binder-free electrode for sodium-ion batteries

et al. 2020

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Scalable Dry Processing of Binder-Free Lithium-Ion Battery Electrodes Enabled by Holey Graphene

Cited by 63 publications

References 30 publications

Thick Electrode Batteries: Principles, Opportunities, and Challenges

Thick Electrode Batteries: Principles, Opportunities, and Challenges

Advanced Matrixes for Binder‐Free Nanostructured Electrodes in Lithium‐Ion Batteries

A novel and fast method to prepare a Cu-supported α-Sb₂S₃@CuSbS₂binder-free electrode for sodium-ion batteries

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Scalable Dry Processing of Binder-Free Lithium-Ion Battery Electrodes Enabled by Holey Graphene

Cited by 63 publications

References 30 publications

Thick Electrode Batteries: Principles, Opportunities, and Challenges

Thick Electrode Batteries: Principles, Opportunities, and Challenges

Advanced Matrixes for Binder‐Free Nanostructured Electrodes in Lithium‐Ion Batteries

A novel and fast method to prepare a Cu-supported α-Sb2S3@CuSbS2binder-free electrode for sodium-ion batteries

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A novel and fast method to prepare a Cu-supported α-Sb₂S₃@CuSbS₂binder-free electrode for sodium-ion batteries