Application of a Sulfur Cathode in Nucleophilic Electrolytes for Magnesium/Sulfur Batteries

Zeng, Linqi; Wang, Nan; Yang, Jun; Wang, Jiulin; Nuli, Yanna

doi:10.1149/2.1131712jes

Cited by 56 publications

(65 citation statements)

References 39 publications

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“…[27] Besides, the high temperature performance in this work outperforms most other batteries that utilize delicately designed sulfur-carbon composites, indicating the superiority of the CuNWs-GN/PI/LLZO separator ( Table 1). [37] These promising results indeed prove the critical role of the CuNWs-GN/PI/LLZO separator in improving the efficient sulfur utilization by the in situ chemical/electrochemical reaction between copper and polysulfides. [37][38][39][40] Especially, even at an elevated temperature of 50 °C and high sulfur loading conditions, the as-designed Mg-S cells show almost 7.6-fold capacity increasement compared to that utilizing typical polyolefin separators.…”

Section: Metal-sulfur Battery Performances Using the As-designed Sepamentioning

confidence: 78%

“…Promisingly, our as constructed Li-S cell demonstrates several folds improvement in respect of both the cycling stability and the specific capacity (≈3.3 times improvement) at 80 °C, as compared to the similar puresulfur work in literature. [37][38][39][40] Especially, even at an elevated temperature of 50 °C and high sulfur loading conditions, the as-designed Mg-S cells show almost 7.6-fold capacity increasement compared to that utilizing typical polyolefin separators. [7,[26][27][28][29][30] In addition, the as-designed Mg-S cells display dramatically improved capacities and cycling performances.…”

Section: Metal-sulfur Battery Performances Using the As-designed Sepamentioning

confidence: 99%

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A Multifunctional Separator Enables Safe and Durable Lithium/Magnesium–Sulfur Batteries under Elevated Temperature

Zhou

Chen

Fang

et al. 2019

Advanced Energy Materials

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Rechargeable metal–sulfur batteries encounter severe safety hazards and fast capacity decay, caused by the flammable and shrinkable separator and unwanted polysulfide dissolution under elevated temperatures. Herein, a multifunctional Janus separator is designed by integrating temperature endurable electrospinning polyimide nonwovens with a copper nanowire‐graphene nanosheet functional layer and a rigid lithium lanthanum zirconium oxide‐polyethylene oxide matrix. Such architecture offers multifold advantages: i) intrinsically high dimensional stability and flame‐retardant capability, ii) excellent electrolyte wettability and effective metal dendritic growth inhibition, and iii) powerful physical blockage/chemical anchoring capability for the shuttled polysulfides. As a consequence, the as constructed lithium–sulfur battery using a pure sulfur cathode displays an outstandingly high discharge capacity of 1402.1 mAh g−1 and a record high cycling stability (approximately average 0.24% capacity decay per cycle within 300 cycles) at 80 °C, outperforming the state‐of‐the‐art results in the literature. Promisingly, a high sulfur mass loading of ≈3.0 mg cm−2 and a record low electrolyte/sulfur ratio of 6.0 are achieved. This functional separator also performs well for a high temperature magnesium–sulfur battery. This work demonstrates a new concept for high performance metal–sulfur battery design and promises safe and durable operation of the next generation energy storage systems.

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Section: Metal-sulfur Battery Performances Using the As-designed Sepamentioning

confidence: 78%

Section: Metal-sulfur Battery Performances Using the As-designed Sepamentioning

confidence: 99%

A Multifunctional Separator Enables Safe and Durable Lithium/Magnesium–Sulfur Batteries under Elevated Temperature

Zhou

Chen

Fang

et al. 2019

Advanced Energy Materials

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“…Apart from high conductivity, the major benefit of a Cu current collector is that it allows for the formation of copper sulfides via reaction with the free sulfur that exists outside the carbonaceous matrix during the cathode drying process at 50 °C. The strong interaction between Cu and S protects the sulfur from reacting with the nucleophilic electrolyte: This increases cycle stability and suppresses the dissolution of polysulfides . This novel concept for the stabilization of the cathode material by copper has also been used by Zeng et al In a similar approach, Cui et al filed a patent about the cathode based on sulfur, a metal sulfide and a ternary copper composite.…”

Section: Cathode Materialsmentioning

confidence: 99%

“…The strong interaction between Cu and S protects the sulfur from reacting with the nucleophilic electrolyte: This increases cycle stability and suppresses the dissolution of polysulfides . This novel concept for the stabilization of the cathode material by copper has also been used by Zeng et al In a similar approach, Cui et al filed a patent about the cathode based on sulfur, a metal sulfide and a ternary copper composite. The metal sulfides comprised FeS 2 , SnS 2 , MoS 2 , Co 3 S 4 , and Ni 2 S 3 .…”

Section: Cathode Materialsmentioning

confidence: 99%

“…In Mg–S batteries, the choice of the current collector has also a great impact on the electrochemical behavior particularly in the case of halogen‐containing corrosive electrolytes, the nature of the electroactive cathode materials and the dissolution of polysulfides during cycling . The currently reported commercial metal‐based current collectors include aluminum foil, stainless‐steel (SS) foil, carbon‐coated aluminum foil, copper, and the anticorrosion alloy Inconel 625 . While Cu is generally considered unstable against chloride‐containing electrolytes, Zeng et al recently reported that a sulfur cathode is compatible with the traditional APC electrolyte using copper as current collector below 1.7 V versus Mg/Mg 2+ .…”

Section: Cathode Materialsmentioning

confidence: 99%

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Rechargeable Magnesium–Sulfur Battery Technology: State of the Art and Key Challenges

Wang

Buchmeiser

2019

Adv Funct Materials

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abundant metal on earth. [19] In view of these merits and the high abundance of sulfur, increasing interest has been raised on post Li-S battery systems, including magnesium-selenium batteries, Mg-S batteries, which display higher energy density, low costs and improved safety in comparison to Li-S batteries. [11,[20][21][22][23] Despite the advantages of Mg-S batteries, major issues in this field are related to the severe overcharge behavior and low sulfur utilization of the cathode during charging and discharging in general, the formation of magnesium polysulfides and the slow diffusion of Mg 2+ , which all result in poor electrochemical behavior. [17,22,24,25] Substantial efforts have been made to improve cell performance so far, including the modification of cathode materials, anodes and separators, [25] the synthesis of novel electrolyte systems, [24,26] which all to some extent can improve the cell behavior. Figure 1d gives a timeline of all the novel findings in the area of Mg-S batteries in each year. Figure 1b demonstrates an overview of the topics addressed in the published research articles in Mg-S batteries. According to this survey, the research community developed a strong preference for investigating novel electrolyte systems, modifying sulfur cathode materials and carrying out mechanistic studies. By contrast, only few research groups devoted their work to the other components of a Mg-S battery, such as the anode and the separator. Major improvements related to the latter two will also be thoroughly discussed in the following sections.Several reviews already discussed the developments in Mg batteries based on intercalation cathode materials. [1,15,[27][28][29][30] By contrast, accounts on Mg batteries containing a sulfur-based conversion cathode, which benefits from high theoretical energy density, a reasonable potential difference with Mg, nontoxicity and high earth abundance [11,31,32] are rare. This review solely refers to Mg-S batteries that use sulfur-based conversion cathodes.The purposes of this review are to summarize and highlight the most up-to-date and novel findings for Mg-S batteries, addressing sulfur-based conversion cathodes and Mg anode materials, separator modifications as well as various electrolyte systems. Furthermore, since the research on Mg-S batteries is still at an initial stage, some challenges, including the capacity decay mechanism, a lack of suitable electrolyte systems and the passivation of the Mg anode, which so far impedes any superior electrochemical performance in Mg-S batteries, will also be addressed. In addition, we also listed and discussed some possible future prospects for high energy Mg-S batteries. Finally, the currently reported Mg-S systems have been summarized in a table for easy comparison.This review on rechargeable Mg-S batteries is arranged in the following sequences. In the first section, currently applied anode materials (various forms of Mg anodes) and prospective anodes are discussed. Next, various sulfur-based conversion cathodes, which mainly...

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A Progress Report on Metal–Sulfur Batteries

Manthiram

2020

Adv Funct Materials

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Nonaqueous conversion-reaction sulfur chemistry has been attracting increasing attention over the past decade for the development of nextgeneration lithium-based batteries. Li-S batteries are currently approaching a nexus stage from lab-scale experiments to possible pragmatic applications. Inspired by the success of Li-S chemistry, other metal-sulfur batteries with a variety of metallic anodes, such as sodium, potassium, magnesium, calcium, and aluminum, have also started to attract attention. In comparison to lithium, Na, Mg, Al, K, and Ca are naturally more abundant and affordable.

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Application of a Sulfur Cathode in Nucleophilic Electrolytes for Magnesium/Sulfur Batteries

Cited by 56 publications

References 39 publications

A Multifunctional Separator Enables Safe and Durable Lithium/Magnesium–Sulfur Batteries under Elevated Temperature

A Multifunctional Separator Enables Safe and Durable Lithium/Magnesium–Sulfur Batteries under Elevated Temperature

Rechargeable Magnesium–Sulfur Battery Technology: State of the Art and Key Challenges

A Progress Report on Metal–Sulfur Batteries

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