Revisiting the Role of Conductivity and Polarity of Host Materials for Long‐Life Lithium–Sulfur Battery

Lee, Byong‐June; Kang, Tong‐Hyun; Hayoung, Lee; Samdani, Jitendra; Jung, Yongju; Zhang, Chunfei; Zhou, Yu; Xu, Gui‐Liang; Cheng, Lei; Byun, Seoungwoo; Lee, Yong Min; Amine, Khalil; Yu, Jong‐Sung

doi:10.1002/aenm.201903934

Cited by 55 publications

(35 citation statements)

References 86 publications

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“…Representing a paradigm shift, Amine, Yu, and colleagues demonstrated the importance of surface polarity over conductivity as the dominant factor for an ideal sulfur‐host. [ 220 ] In their latest study, two mesoporous hosts with similar pore structures were contrasted: nonconductive but highly polar mesoporous silica versus highly conductive but nonpolar mesoporous carbon. Despite higher initial capacity (i.e., sulfur utilization) of the carbon host as one would expect from its better conductivity, polar mesoporous silica exhibited better polysulfide confinement with 54% capacity retention after 2000 cycles, compared to only 15% in nonpolar mesoporous carbon, with Coulombic efficiencies of 96% and 83%, respectively.…”

Section: Prospects and Future Outlook: Sodium–sulfur Batteries And Bementioning

confidence: 99%

Room‐Temperature Sodium–Sulfur Batteries and Beyond: Realizing Practical High Energy Systems through Anode, Cathode, and Electrolyte Engineering

Eng

Kumar

Zhang

et al. 2021

Advanced Energy Materials

120

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The increasing energy demands of society today have led to the pursuit of alternative energy storage systems that can fulfil rigorous requirements like cost‐effectiveness and high storage capacities. Based fundamentally on earth‐abundant sodium and sulfur, room‐temperature sodium–sulfur batteries are a promising solution in applications where existing lithium‐ion technology remains less economically viable, particularly in large‐scale stationary systems such as grid‐level storage. Here, the key challenges in the field are first highlighted, followed by comprehensive analyses of accessible strategies to overcome them, starting from engineering of the anode–electrolyte interface in both liquid and solid electrolytes. Recently reported polymer and solid‐state electrolytes are also surveyed. Thereafter, the core principles guiding use‐inspired design of cathode architectures, covering the spectrum of elemental sulfur and polysulfide cathodes, to emerging host structures, and covalent composites are focused upon. Future prospects are explored, with insights into other alkali‐metal systems beyond sodium–sulfur batteries, such as the potassium–sulfur battery. Finally a conclusion is provided by outlining the research directions necessary to attain high energy sodium–sulfur devices, and potential solutions to issues concerning large‐scale production, so as to ultimately realize widespread deployment of practical energy storage systems.

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Section: Prospects and Future Outlook: Sodium–sulfur Batteries And Bementioning

confidence: 99%

Room‐Temperature Sodium–Sulfur Batteries and Beyond: Realizing Practical High Energy Systems through Anode, Cathode, and Electrolyte Engineering

Eng

Kumar

Zhang

et al. 2021

Advanced Energy Materials

120

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“…The advantages of advanced RT-Li/Na sulfur systems offer the high theoretical energy density of Li/Na metals, their similar chemical properties, the natural abundance of elements, capability for low-temperature operation, and environmental friendliness. [7][8][9][10][11][12][13][14][15][16][17] These advantages of RT-Li/S and RT-Na/S cells make them two of the most promising candidates for energy storage devices in the near future. [18][19][20] Challenges, however, still remained for achieving efficient conversion reactions of sulfur species, which limit the application of RT-Li/Na sulfur batteries with regard to low reversible capacity as well as rapid capacity decay.…”

Section: Introductionmentioning

confidence: 99%

“…Rechargeable lithium/sodium–sulfur cells, working at room temperature (RT‐Li/S and RT‐Na/S cells), as the most important parts of metal batteries, have been extensively investigated and partially commercialized. The advantages of advanced RT‐Li/Na sulfur systems offer the high theoretical energy density of Li/Na metals, their similar chemical properties, the natural abundance of elements, capability for low‐temperature operation, and environmental friendliness 7–17 . These advantages of RT‐Li/S and RT‐Na/S cells make them two of the most promising candidates for energy storage devices in the near future 18–20 .…”

Section: Introductionmentioning

confidence: 99%

Manipulating metal–sulfur interactions for achieving high‐performance S cathodes for room temperature Li/Na–sulfur batteries

Dai

Liu

et al. 2021

Carbon Energy

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Rechargeable lithium/sodium-sulfur batteries working at room temperature (RT-Li/S, RT-Na/S) appear to be a promising energy storage system in terms of high theoretical energy density, low cost, and abundant resources in nature.They are, thus, considered as highly attractive candidates for future application in energy storage devices. Nevertheless, the solubility of sulfur species, sluggish kinetics of lithium/sodium sulfide compounds, and high reactivity of metallic anodes render these cells unstable. As a consequence, metal-sulfur batteries present low reversible capacity and quick capacity loss, which hinder their practical application. Investigations to address these issues regarding S cathodes are critical to the increase of their performance and our fundamental understanding of RT-Li/S and RT-Na/S battery systems. Metal-sulfur interactions, recently, have attracted considerable attention, and there have been new insights on pathways to high-performance RT-Li/Na sulfur batteries, due to the following factors: (1) deliberate construction of metal-sulfur interactions can enable a leap in capacity; (2) metal-sulfur interactions can confine S species, as well as sodium sulfide compounds, to stop shuttle effects; (3) traces of metal species can help to encapsulate a high loading mass of sulfur with high-cost efficiency; and (4) metal components make electrodes more conductive. In this review, we highlight the latest progress in sulfide immobilization via constructing metal bonding between various metals and S cathodes. Also, we summarize the storage mechanisms of Li/Na as well as the metal-sulfur interaction mechanisms. Furthermore, the current challenges and future remedies in terms of intact confinement and optimization of the electrochemical performance of RT-Li/Na sulfur systems are discussed in this review.

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“…Particularly, the formed intermediate long‐chain LPSs can easily dissolve into organic electrolytes and diffuse between the cathode and the anode driven by the concentration gradient, which is the commonly called “shuttle effect”, leading to a severe loss of active materials, severe self‐discharge and rapid capacity decay of the battery [9,10] . Besides, due to the insulting nature of elemental sulfur and discharged product Li 2 S, Li−S cells usually have a high internal resistance, resulting in poor rate performance and low utilization of active S material [11] . Furthermore, since the density difference between the sulfur and discharged product Li 2 S, the cathode suffers from a huge volume change (∼80%) during discharge/charge processes, further causing the inferior cycling stability of electrodes [12] …”

Section: Introductionmentioning

confidence: 99%

Recent Advances of Freestanding Cathodes for Li‐S Batteries

Zhang

Liu

Yang

et al. 2021

Chemistry An Asian Journal

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Lithium‐sulfur batteries (LSBs) with high energy density and low cost have been recognized as one of the most promising next‐generation energy storage systems. Although it has taken decades of development, the practical application of LSBs has been hindered by several inherent obstacles, particularly the severe shuttle effect and sluggish reaction kinetics in the sulfur cathode. Various strategies have been proposed to address these problems via rational design of electrode materials and configurations. Freestanding sulfur cathode could be a promising strategy to improve the sulfur mass loading at the cathode level and energy density of LSBs. This minireview will briefly summary the recent advances in freestanding cathodes for LSBs. The advantages and disadvantages of various freestanding cathodes are discussed and the prospects for the development of flexible cathodes are envisioned.

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Revisiting the Role of Conductivity and Polarity of Host Materials for Long‐Life Lithium–Sulfur Battery

Cited by 55 publications

References 86 publications

Room‐Temperature Sodium–Sulfur Batteries and Beyond: Realizing Practical High Energy Systems through Anode, Cathode, and Electrolyte Engineering

Room‐Temperature Sodium–Sulfur Batteries and Beyond: Realizing Practical High Energy Systems through Anode, Cathode, and Electrolyte Engineering

Manipulating metal–sulfur interactions for achieving high‐performance S cathodes for room temperature Li/Na–sulfur batteries

Recent Advances of Freestanding Cathodes for Li‐S Batteries

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