Lithium Azide as an Electrolyte Additive for All‐Solid‐State Lithium–Sulfur Batteries

Eshetu, Gebrekidan Gebresilassie; Judez, Xabier; Li, Chunmei; Bondarchuk, Oleksandr; Rodrı́guez-Martı́nez, Lide M.; Zhang, Heng; Armand, Michel

doi:10.1002/anie.201709305

Cited by 219 publications

(150 citation statements)

References 31 publications

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“…Despite the significant improvement on the Li anode/electrolyte interface by the addition of Al 2 O 3 has been demonstrated, it is still necessary to understand its interaction with PS in pursuit of its practical application Li−S cells. Figure b shows visual experiments where Al 2 O 3 nano‐particles added to a Li 2 S 6 containing 1,2‐dimethoxyethane (DME, with an analogous chemical structure to PEO) solution. The mixture was stirred 1 h prior removing of solid particles by centrifugation.…”

Section: Figurementioning

confidence: 99%

Understanding the Role of Nano‐Aluminum Oxide in All‐Solid‐State Lithium‐Sulfur Batteries

et al. 2018

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Aluminum oxide (Al2O3) is a well‐known electrolyte filler for stabilizing the Li‐metal (Li0) anode in all‐solid‐state Li0‐based batteries. However, its strong interactions with lithium polysulfides (PS) hinder the direct application of Al2O3‐added electrolytes in all‐solid‐state lithium‐sulfur batteries (ASSLSBs). Herein, the role of Al2O3 in ASSLSBs both as electrolyte filler and cathode additive is studied. The combination of Al2O3‐added electrolyte and Al2O3‐added S8 cathode with optimum cell configuration could deliver an unprecedented discharge capacity of 0.85 mAh cm−2 (C/10, 30 cycles) for polymer‐based ASSLSBs. These results suggest that the rational incorporation of Al2O3 can lead simultaneously to PS anchoring and Li0 anode stabilizing benefits from the ceramic filler, thus improving the electrochemical performance of ASSLSBs.

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Section: Figurementioning

confidence: 99%

Understanding the Role of Nano‐Aluminum Oxide in All‐Solid‐State Lithium‐Sulfur Batteries

et al. 2018

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“…[20,[22][23][24] For these reasons almost all electrolytes, including solid electrolytes, undergo decomposition as soon they come in contact with Li resulting in a variety of reduction products (Figure 3). [25][26][27][28][29] The extremely high reactivity of Li anode has been spectroscopically confirmed by Fourier-transform infrared spectroscopy (FTIR), X-ray photoelectron spectroscopy (XPS), and energy dispersive spectroscopy (EDS) measurements, [25,30] and electrochemically observed with the help of chronopotentiometry, chronoamperometry, cyclic voltammetry, electrochemical quartz crystal microbalance (EQCM), galvanostatic/potentiostatic intermittent titrations (GITT, PITT), and electrochemical impedance spectroscopy (EIS). [25,[31][32][33][34][35] The reactivity of Li anode has also been theoretically confirmed.…”

Section: Reactivity Of LI Metalmentioning

confidence: 98%

Section: Challenges Faced By LI Metal Anodesmentioning

confidence: 99%

“…[25,[31][32][33][34][35] The reactivity of Li anode has also been theoretically confirmed. [36][37][38] It has been found that the electrolyte salts ( Figure 3a) [29] and additives ( Figure 3b) [28] are repeatedly reduced/precipitated on the Li surface from solution. [39][40][41][42] Some of the aprotic salts, such as LiBF 4 , LiPF 6 , LiN(SO 2 CF 3 ) 2 , and LiSO 3 CF 3 are moisture sensitive and produce HF as the hydrolysis product due to the presence of trace moisture in the electrolyte solvents, which immediately react with Li metal anode until the electrolyte is vanished.…”

Section: Reactivity Of LI Metalmentioning

confidence: 99%

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Key Aspects of Lithium Metal Anodes for Lithium Metal Batteries

Ghazi

Sun

et al. 2019

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Rechargeable batteries are considered promising replacements for environmentally hazardous fossil fuel‐based energy technologies. High‐energy lithium‐metal batteries have received tremendous attention for use in portable electronic devices and electric vehicles. However, the low Coulombic efficiency, short life cycle, huge volume expansion, uncontrolled dendrite growth, and endless interfacial reactions of the metallic lithium anode are major obstacles in their commercialization. Extensive research efforts have been devoted to address these issues and significant progress has been made by tuning electrolyte chemistry, designing electrode frameworks, discovering nanotechnology‐based solutions, etc. This Review aims to provide a conceptual understanding of the current issues involved in using a lithium metal anode and to unveil its electrochemistry. The most recent advancements in lithium metal battery technology are outlined and suggestions for future research to develop a safe and stable lithium anode are presented.

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“…Preliminary research has developed a variety of polymers such as PEO, PEMO, and PEGDME and investigate the electrochemical performance with these SSEs in Li-S batteries [359,[402][403][404][405][406][407]. Furthermore, novel polymer electrolytes with nanostructure design, improved ionic conductivity and advanced characterizations were also conducted [396,408,409]. Many polymer electrolytes possess significant advantages in flexibility and chemical compatibility that are unrivaled by other SSEs.…”

Section: Polymer Electrolyte-based Li-s Batteriesmentioning

confidence: 99%

Structural Design of Lithium–Sulfur Batteries: From Fundamental Research to Practical Application

Yang

Adair

et al. 2018

Electrochem. Energ. Rev.

310

198

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Lithium-sulfur (Li-S) batteries have been considered as one of the most promising energy storage devices that have the potential to deliver energy densities that supersede that of state-of-the-art lithium ion batteries. Due to their high theoretical energy density and cost-effectiveness, Li-S batteries have received great attention and have made great progress in the last few years. However, the insurmountable gap between fundamental research and practical application is still a major stumbling block that has hindered the commercialization of Li-S batteries. This review provides insight from an engineering point of view to discuss the reasonable structural design and parameters for the application of Li-S batteries. Firstly, a systematic analysis of various parameters (sulfur loading, electrolyte/sulfur (E/S) ratio, discharge capacity, discharge voltage, Li excess percentage, sulfur content, etc.) that influence the gravimetric energy density, volumetric energy density and cost is investigated. Through comparing and analyzing the statistical information collected from recent Li-S publications to find the shortcomings of Li-S technology, we supply potential strategies aimed at addressing the major issues that are still needed to be overcome. Finally, potential future directions and prospects in the engineering of Li-S batteries are discussed.

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Lithium Azide as an Electrolyte Additive for All‐Solid‐State Lithium–Sulfur Batteries

Cited by 219 publications

References 31 publications

Understanding the Role of Nano‐Aluminum Oxide in All‐Solid‐State Lithium‐Sulfur Batteries

Understanding the Role of Nano‐Aluminum Oxide in All‐Solid‐State Lithium‐Sulfur Batteries

Key Aspects of Lithium Metal Anodes for Lithium Metal Batteries

Structural Design of Lithium–Sulfur Batteries: From Fundamental Research to Practical Application

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