Catalytic oxidation of Li
            <sub>2</sub>
            S on the surface of metal sulfides for Li−S batteries

Zhou, Guangmin; Tian, Hongjing; Jin, Yang; Tao, Xinyong; Liu, Bofei; Wei, Fei; Seh, Zhi Wei; Zhuo, Denys; Liu, Yayuan; Sun, Jie; Zhao, Jie; Zu, Chenxi; Wu, David; Zhang, Qianfan; Cui, Yi

doi:10.1073/pnas.1615837114

Cited by 1,056 publications

(958 citation statements)

References 42 publications

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“…Cui and co‐workers found that metal sulfides accelerate the oxidation of Li 2 S to sulfur ( Figure 6 ). 12 Electrochemical measurements and XPS studies show that VS 2 , CoS 2 , and TiS 2 have higher binding energies toward Li 2 S 6 . First‐principles calculations show that the strong interaction between LiPSs and metal sulfides lowers the overpotential for the Li 2 S decomposition.…”

Section: Catalytic Metal‐based Hosts For Li–s Batteriesmentioning

confidence: 95%

Catalytic Effects in Lithium–Sulfur Batteries: Promoted Sulfur Transformation and Reduced Shuttle Effect

et al. 2017

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Lithium–sulfur (Li–S) battery has emerged as one of the most promising next‐generation energy‐storage systems. However, the shuttle effect greatly reduces the battery cycle life and sulfur utilization, which is great deterrent to its practical use. This paper reviews the tremendous efforts that are made to find a remedy for this problem, mostly through physical or chemical confinement of the lithium polysulfides (LiPSs). Intrinsically, this “confinement” has a relatively limited effect on improving the battery performance because in most cases, the LiPSs are “passively” blocked and cannot be reused. Thus, this strategy becomes less effective with a high sulfur loading and ultralong cycling. A more “positive” method that not only traps but also increases the subsequent conversion of LiPSs back to lithium sulfides is urgently needed to fundamentally solve the shuttle effect. Here, recent advances on catalytic effects in increasing the rate of conversion of soluble long‐chain LiPSs to insoluble short‐chain Li2S2/Li2S, and vice versa, are reviewed, and the roles of noble metals, metal oxides, metal sulfides, metal nitrides, and some metal‐free materials in this process are highlighted. Challenges and potential solutions for the design of catalytic cathodes and interlayers in Li–S battery are discussed in detail.

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Section: Catalytic Metal‐based Hosts For Li–s Batteriesmentioning

confidence: 95%

Catalytic Effects in Lithium–Sulfur Batteries: Promoted Sulfur Transformation and Reduced Shuttle Effect

et al. 2017

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“…In particular, a sudden capacity drop was observed after the 50 th cycle, which was mainly attributed to the low utilization of sulfur and subsequent continuous formation of a large amount of insulating S/Li 2 S products during prolonged cycling. 46,47 A comparison of the different rate capabilities arising from the use of different electrolyte is given in Figure 7d. For all current densities, the cell using the 0.5 M LiTFSI electrolyte delivered a higher discharge capacity than the cell using the 1 M LiTFSI electrolyte.…”

Section: 45mentioning

confidence: 99%

Controlling the Wettability between Freestanding Electrode and Electrolyte for High Energy Density Lithium-Sulfur Batteries

Hwang

Kim

Sun

2017

J. Electrochem. Soc.

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The present study demonstrates how to improve the electrochemical performance and energy density of lithium-sulfur batteries based on controlling the wettability between the freestanding electrode and the electrolyte. First, to improve the volumetric energy density, we reduced the thickness of freestanding electrode by the applying pressure. Second, in order to improve electrolyte conductivity and wettability for pressed freestanding electrode, we reduced the viscosity of electrolyte solution by reducing the LiTFSI salt concentration. Through these controls, the Li-S cell is constructed from a pressed freestanding carbon nanotube-sulfur cathode, 0.5 M LiTFSI in DME/DOL with 0.4 M LiNO 3 as a low-viscosity electrolyte (0.72 cP), and Li-metal foil as an anode. As a result, we can obtain a high discharge capacity of 1,400 mAh g −1 at 0.1 C and excellent cycle retention of 95% after 80 cycles at 0.5 C in coin-type cell. In addition, scale-up (3 by 5 cm) pouch-type Li-S cell delivers a high discharge capacity of 500 mAh at 0.1 C with high gravimetric (954. In order to mitigate the global environmental issues associated with the use of fossil fuels and the resulting greenhouse gas emissions, clean and sustainable energy production and storage technologies are urgently needed.1,2 In this context, lithium-ion battery (LIB) technology has progressed considerably, with continuing applications in potential energy storage devices. However, current LIBs have limited applications in electric vehicles, hybrid electric vehicles, and power grids, owing to their low theoretical energy densities.3-6 Therefore, for mid-to-large-scale applications, it is imperative that we explore alternatives that offer the possibility of going beyond the limits of the intercalation chemistry of current Li-ion technology. 7The lithium-sulfur (Li-S) battery has emerged as a next-generation rechargeable battery, owing to the involvement of multiple electrons during the redox reactions between Li and S, which provides high theoretical energy density (2,600 Wh kg −1 ) and specific capacity (1,675 mAh g −1 ). 8,9 In addition, due to abundance of elemental sulfur and its environmental compatibility, Li-S battery has been considered the much more attractive power sources. Despite these advantages, current Li-S battery have various disadvantages such as poor electrical conductivities of sulfur and Li 2 S, 10,11 undesirable shuttle reactions, 12,13 and huge volume changes of sulfur (∼80%) upon cycling, 14 which have severely delayed the commercialization of Li-S batteries.In order to overcome these problems, various strategies have been implemented to improve the design of both the electrode and the electrolytes materials.15-23 A freestanding electrode is one of attractive choice as the cathode for a Li-S battery, because it is fabricated without a binder or any powdery conductive materials, thereby allowing higher percentages of active material (S 8 ) in the cathode. 24 In addition, by taking advantage of their porous structure, the use of freestanding ele...

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“…The contents of Cu and S obtained from XPS results are much lower than added. [27,[34][35][36] A high ratio of pyridinic-N (41.3 % at. The XPS characterization technology only reflects the surface element information within the depth of 3 nm.…”

Section: Structural and Morphological Featuresmentioning

confidence: 99%

Hierarchically Designed CNF/S−Cu/CNF Nonwoven Electrode as Free‐Standing Cathode for Lithium−Sulfur Batteries

Bian

Yuan

et al. 2019

Batteries & Supercaps

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A flexible lithiumÀsulfur (LiÀS) battery cathode is prepared through uniformly depositing sulfur solution into an electrospun N-rich and Cu-decorated nonwoven carbon nanofiber (CNF) film to form sandwich structured CNF/SÀCu/CNF film electrodes. As a free-standing cathode of LiÀS battery, the unique structural CNF/SÀCu/CNF composite cathodes exhibit high capacity and rate capability as well as long cycling stability. The electrodes can deliver a reversible capacity of 1295 mAh g À1 at a current density of 0.1 A g À1 , and maintain more than 530 mAh g À1 even at a high current rate of 1 A g À1 after 300 cycles along with a Coulombic efficiency close to 100 %. The exceptional performance of CNF/SÀCu/CNF as cathode in LiÀS batteries is attributed to a synergistic contribution from the CNF layers, the decorated-Cu nanoparticles and the doped N element in CNF, which can physically and chemically stabilize S and provide fast electronic conductivity. This facile strategy will pave the way to construct high-performance flexible LiÀS batteries.

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Catalytic oxidation of Li ₂ S on the surface of metal sulfides for Li−S batteries

Cited by 1,056 publications

References 42 publications

Catalytic Effects in Lithium–Sulfur Batteries: Promoted Sulfur Transformation and Reduced Shuttle Effect

Catalytic Effects in Lithium–Sulfur Batteries: Promoted Sulfur Transformation and Reduced Shuttle Effect

Controlling the Wettability between Freestanding Electrode and Electrolyte for High Energy Density Lithium-Sulfur Batteries

Hierarchically Designed CNF/S−Cu/CNF Nonwoven Electrode as Free‐Standing Cathode for Lithium−Sulfur Batteries

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Catalytic oxidation of Li 2 S on the surface of metal sulfides for Li−S batteries

Cited by 1,056 publications

References 42 publications

Catalytic Effects in Lithium–Sulfur Batteries: Promoted Sulfur Transformation and Reduced Shuttle Effect

Catalytic Effects in Lithium–Sulfur Batteries: Promoted Sulfur Transformation and Reduced Shuttle Effect

Controlling the Wettability between Freestanding Electrode and Electrolyte for High Energy Density Lithium-Sulfur Batteries

Hierarchically Designed CNF/S−Cu/CNF Nonwoven Electrode as Free‐Standing Cathode for Lithium−Sulfur Batteries

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Catalytic oxidation of Li ₂ S on the surface of metal sulfides for Li−S batteries