Screen printed cathode for non-aqueous lithium–oxygen batteries

Jung, Chang Young; Zhao, Tianshou; An, Liang; Zeng, Lin; Wei, Zhaohuan

doi:10.1016/j.jpowsour.2015.07.089

Cited by 21 publications

(13 citation statements)

References 49 publications

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“…Zhou [105] reviewed 3D printing energy storage devices with a sandwich-type and in-plane architecture and demonstrated that the electrochemical energy storage systems can be greatly promoted with 3D printing. Lewis et al [106,107] reported 3D fully printed electrodes for Li-ion batteries. Li 4 Ti 5 O 12 (LTO) and LiFePO 4 (LFP) were separately employed as anode and cathode materials.…”

Section: D Printingmentioning

confidence: 99%

Recent Progress of Metal–Air Batteries—A Mini Review

et al. 2019

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With the ever-increasing demand for power sources of high energy density and stability for emergent electrical vehicles and portable electronic devices, rechargeable batteries (such as lithium-ion batteries, fuel batteries, and metal–air batteries) have attracted extensive interests. Among the emerging battery technologies, metal–air batteries (MABs) are under intense research and development focus due to their high theoretical energy density and high level of safety. Although significant progress has been achieved in improving battery performance in the past decade, there are still numerous technical challenges to overcome for commercialization. Herein, this mini-review summarizes major issues vital to MABs, including progress on packaging and crucial manufacturing technologies for cathode, anode, and electrolyte. Future trends and prospects of advanced MABs by additive manufacturing and nanoengineering are also discussed.

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Section: D Printingmentioning

confidence: 99%

Recent Progress of Metal–Air Batteries—A Mini Review

et al. 2019

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“…Thin cathode manufacturing is possible with tape casting or with any other method capable of producing films with an appropriate thickness, such as spraying [61][62][63][64][65] or screen-printing. [66][67][68][69][70] Rather, the key to thin cathode manufacturing is high performance, stable, highly productive slurry manufacturing technology. [71][72][73][74] Of course, thin cathode manufacturing technology is applicable not only to FeS 2 but also to other cathode materials.…”

Section: Fesmentioning

confidence: 99%

Recent Progress in Cathode Materials for Thermal Batteries

Kang

Cheong

et al. 2019

J. Korean Ceram. Soc

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Thermal batteries are reserve batteries with molten salts as an electrolyte, which activates at high temperature. Due to their excellent reliability, long shelf life, and mechanical robustness, thermal batteries are used in military applications. A high-performance cathode for thermal batteries should be considered in terms of its high capacity, high voltage, and high thermal stability. Research progress on cathode materials from the recent decade is reviewed in this article. The major directions of research were surface modification, compounding of existing materials, fabrication of thin film cathode, and development of new materials. In order to develop a high-performance cathode, a proper combination of these research directions is required while considering mass production and cost.

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“…It has been found that the morphology and quantity of discharge products can be regulated by controlling the pore sizes and porosity of carbon electrodes [59]. For example, Zhao et al [60] reported a novel screen-printing method for preparing positive electrode materials, which could induce the generation of evenly distributed large crack-like pores (~10 µm). During discharge, such large pores facilitated the uniform deposition of Li 2 O 2 products without pore clogging and electrical passivation.…”

Section: Structural Designmentioning

confidence: 99%

Recent Progress on Catalysts for the Positive Electrode of Aprotic Lithium-Oxygen Batteries †

2019

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Rechargeable aprotic lithium-oxygen (Li-O2) batteries have attracted significant interest in recent years owing to their ultrahigh theoretical capacity, low cost, and environmental friendliness. However, the further development of Li-O2 batteries is hindered by some ineluctable issues, such as severe parasitic reactions, low energy efficiency, poor rate capability, short cycling life and potential safety hazards, which mainly stem from the high charging overpotential in the positive electrode side. Thus, it is of great significance to develop high-performance catalysts for the positive electrode in order to address these issues and to boost the commercialization of Li-O2 batteries. In this review, three main categories of catalyst for the positive electrode of Li-O2 batteries, including carbon materials, noble metals and their oxides, and transition metals and their oxides, are systematically summarized and discussed. We not only focus on the electrochemical performance of batteries, but also pay more attention to understanding the catalytic mechanism of these catalysts for the positive electrode. In closing, opportunities for the design of better catalysts for the positive electrode of high-performance Li-O2 batteries are discussed.

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Screen printed cathode for non-aqueous lithium–oxygen batteries

Cited by 21 publications

References 49 publications

Recent Progress of Metal–Air Batteries—A Mini Review

Recent Progress of Metal–Air Batteries—A Mini Review

Recent Progress in Cathode Materials for Thermal Batteries

Recent Progress on Catalysts for the Positive Electrode of Aprotic Lithium-Oxygen Batteries †

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