Review—Non-Carbonaceous Materials as Cathodes for Lithium-Sulfur Batteries

Arias, Analía Natalí; Tesio, Alvaro Yamil; Flexer, Victoria

doi:10.1149/2.0181801jes

Cited by 28 publications

(17 citation statements)

References 96 publications

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“…The fabrication of sulfur‐polyacrylonitrile composites (SPAN), which are classical representatives of these type of functional materials, has been proved to be very promising . Moreover, polymers offer soft structures that can undergo significant volume changes and improve the conductivity of composite cathodes . Although the precursors, polyacrylonitrile (PAN) and elemental sulfur, are the same in all reported SPAN composites, the specific synthetic protocol varies considerably in temperature, heating time, molar ratio of the reactants, and final sulfur content.…”

Section: Introductionmentioning

confidence: 92%

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Low‐Temperature Synthesis of a Sulfur‐Polyacrylonitrile Composite Cathode for Lithium‐Sulfur Batteries

et al. 2020

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Through a novel synthesis process, a novel sulfurized polyacrylonitrile (SPAN) composite, noted as DH-150-300-SPAN, was prepared and tested as cathode material for lithium sulfur (LiÀ S) batteries. The reported process involves two heating steps at low temperature. The first plateau at 150°C melts elemental sulfur, while the second, at 300°C, produces the cycling of polyacrylonitrile, and incorporates sulfur to the cyclic polymeric structure. A fully morphological and electrochemical characterization was carried out. The SPAN composite contains (38.3 � 0.2) % S. LiÀ S batteries assembled using these cathodes have shown good performance, reaching high and stable capacity values, above 1000 mAh g À 1 S after 150 cycles at 0.1 C. This is the first time that stable cycling is achieved for a SPAN composite synthesized at such low temperatures and for short heating treatments. Our work describes an easy route to prepare a promising candidate for cathode material of LiÀ S batteries by using a low-cost process and low-cost materials.[a] Dr.

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Section: Introductionmentioning

confidence: 92%

“…With the purpose to solve these problems, great effort has been made by modifying cathode composition, electrolyte, lithium anode, and separator . A special interest has been put on the cathode material modification in order to produce a functional material for energy storage.…”

Section: Introductionmentioning

confidence: 99%

Low‐Temperature Synthesis of a Sulfur‐Polyacrylonitrile Composite Cathode for Lithium‐Sulfur Batteries

et al. 2020

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“…Lithium demand is expected to grow continuously and dramatically in the coming years as different types of lithium batteries are the most promising candidates for powering electric or hybrid vehicles [10,11]. Lithium batteries include both current technologies such as lithium-ion and growing battery technologies such as lithium-sulfur or lithium-air [12][13][14][15].…”

Section: Introductionmentioning

confidence: 99%

Lithium Recovery from Brines Including Seawater, Salt Lake Brine, Underground Water and Geothermal Water

Samadiy¹,

Yu²,

Li³

et al. 2020

Thermodynamics and Energy Engineering

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Demand to lithium rising swiftly as increasing due to its diverse applications such as rechargeable batteries, light aircraft alloys, air purification, medicine and nuclear fusion. Lithium demand is expected to triple by 2025 through the use of batteries, particularly electric vehicles. The lithium market is expected to grow from 184,000 TPA of lithium carbonate to 534,000 TPA by 2025. To ensure the growing consumption of lithium, it is necessary to increase the production of lithium from different resources. Natural lithium resources mainly associate within granite pegmatite type deposit (spodumene and petalite ores), salt lake brines, seawater and geothermal water. Among them, the reserves of lithium resource in salt lake brine, seawater and geothermal water are in 70-80% of the total, which are excellent raw materials for lithium extraction. Compared with the minerals, the extraction of lithium from water resources is promising because this aqueous lithium recovery is more abundant, more environmentally friendly and cost-effective.

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“…These conductive additives need to be critically designed for maintaining the electrode structure during cycling. This is due to the large volume change of 80% when converting sulfur (S 8 ) to Li 2 S. As the cell is cycled, the structure of the electrode is disrupted as sulfur loses contact with carbon, resulting in an interruption of the conductive pathway and a decline in cycle life . Additionally, the intermediate lithium polysulfides, (Li 2 S x , x = 4–8, LiPS), are produced from the conversion‐reaction chemistry of sulfur and readily dissolve in the organic electrolyte, causing LiPS shuttling between the two electrodes .…”

Section: Introductionmentioning

confidence: 99%

Pyrrolic‐Type Nitrogen‐Doped Hierarchical Macro/Mesoporous Carbon as a Bifunctional Host for High‐Performance Thick Cathodes for Lithium‐Sulfur Batteries

Han

Chung

Manthiram

2019

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Lithium‐sulfur (Li‐S) batteries are highly considered as a next‐generation energy storage device due to their high theoretical energy density. For practical viability, reasonable active‐material loading of >4.0 mg cm−2 must be employed, at a cost to the intrinsic instability of sulfur cathodes. The incursion of lithium polysulfides (LiPS) at higher sulfur loadings results in low active material utilization and poor cell cycling capability. The use of high‐surface‐area hierarchical macro/mesoporous inverse opal (IOP) carbons to investigate the effects of pore volume and surface area on the electrochemical stability of high‐loading, high‐thickness cathodes for Li‐S batteries is presented here. The IOP carbons are additionally doped with pyrrolic‐type nitrogen groups (N‐IOP) to act as a polar polysulfide mediator and enhance the active‐material reutilization. With a high sulfur loading of 6.0 mg cm−2, the Li‐S cells assembled with IOP and N‐IOP carbons are able to attain a high specific capacity of, respectively, 1242 and 1162 mA h g−1. The N‐IOP enables the Li‐S cells to demonstrate good electrochemical performance over 300 cycles.

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Review—Non-Carbonaceous Materials as Cathodes for Lithium-Sulfur Batteries

Cited by 28 publications

References 96 publications

Low‐Temperature Synthesis of a Sulfur‐Polyacrylonitrile Composite Cathode for Lithium‐Sulfur Batteries

Low‐Temperature Synthesis of a Sulfur‐Polyacrylonitrile Composite Cathode for Lithium‐Sulfur Batteries

Lithium Recovery from Brines Including Seawater, Salt Lake Brine, Underground Water and Geothermal Water

Pyrrolic‐Type Nitrogen‐Doped Hierarchical Macro/Mesoporous Carbon as a Bifunctional Host for High‐Performance Thick Cathodes for Lithium‐Sulfur Batteries

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