Electrochemical Kinetic Modulators in Lithium–Sulfur Batteries: From Defect‐Rich Catalysts to Single Atomic Catalysts

Zhang, Jing; Chen, You; Lin, Hongzhen; Wang, Jian

doi:10.1002/eem2.12250

Cited by 123 publications

(68 citation statements)

References 175 publications

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“…The massive demands in smart portable devices, electromobility and stationary storage systems push the developments of high-energy-density battery systems. − Lithium metal anode exhibits high theoretical capacity and the low potential (−3.04 V vs SHE). , However, the dendrite resulted from random lithium plating behaviors and sluggish surface atom diffusion, and uneven solid electrolyte interphase (SEI) prevent its wide applications. − Moreover, large volumetric changes during cycling will break down the fragile SEI so that fresh SEI will be continuously formed at the Li/electrolyte interface, exhausting the limited electrolyte . These cross-linked issues would lead to severe safety problems and significantly degraded performances .…”

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confidence: 99%

Lithium Atom Surface Diffusion and Delocalized Deposition Propelled by Atomic Metal Catalyst toward Ultrahigh-Capacity Dendrite-Free Lithium Anode

et al. 2022

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Lithium metal anode possesses overwhelming capacity and low potential but suffers from dendrite growth and pulverization, causing short lifespan and low utilization. Here, a fundamental novel insight of using single-atomic catalyst (SAC) activators to boost lithium atom diffusion is proposed to realize delocalized deposition. By combining electronic microscopies, time-of-flight secondary ion mass spectrometry, theoretical simulations, and electrochemical analyses, we have unambiguously depicted that the SACs serve as kinetic activators in propelling the surface spreading and lateral redistribution of the lithium atoms for achieving dendrite-free plating morphology. Under the impressive capacity of 20 mA h cm–2, the Li modified with SAC-activator exhibits a low overpotential of ∼50 mV at 5 mA cm–2, a long lifespan of 900 h, and high Coulombic efficiencies during 150 cycles, much better than most literature reports. The so-coupled lithium–sulfur full battery delivers high cycling and rate performances, showing great promise toward the next-generation lithium metal batteries.

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confidence: 99%

Lithium Atom Surface Diffusion and Delocalized Deposition Propelled by Atomic Metal Catalyst toward Ultrahigh-Capacity Dendrite-Free Lithium Anode

et al. 2022

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“…This phenomenon explains that the high-temperature NH 3 treatment is an effective method to achieve N doping and generate oxygen vacancies within the N-Co 2 VO 4 -Co heterojunction could adjust the electronic structure, [30] which might be beneficial for adsorption and catalysis of LiPSs and Li + transmission. [31] Given the homogeneous perforated flake morphology with nanoscale thickness as well as the polar heterostructures with abundant exposure of defects, the as-prepared N-Co 2 VO 4 -Co is supposed to exhibit favorable capability in inhibiting the shuttle effects and accelerating the sulfur related electrochemistry. In Li-S batteries, the conversion and utilization of polysulfides play a decisive role in its electrochemical performance.…”

Section: Resultsmentioning

confidence: 99%

Rational Design of the Lotus‐Like N‐Co₂VO₄‐Co Heterostructures with Well‐Defined Interfaces in Suppressing the Shuttle Effect and Dendrite Growth in Lithium–Sulfur Batteries

Zhou

Zhao

et al. 2021

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The shuttle effect caused by soluble lithium polysulfides (LiPSs) and intrinsic slow electrochemical transformation from LiPSs to Li2S/Li2S2 will induce undesirable cycling performance, which is the primary obstruct limiting the practical applications of lithium–sulfur (Li–S) batteries. Here a convenient method is designed to fabricate the 2D louts‐like N‐Co2VO4‐Co heterostructures with well‐abundant interfaces and oxygen vacancies (Vo), endowing the materials with both “sulfiphilic” and “lithiophilic” features. When employed as the modification layer coated on commercial Celgard 2400 separator, the as‐prepared N‐Co2VO4‐Co/PP with synergistic adsorption‐electrocatalysis effects achieves desirable sulfur electrochemistry, thus showing a high initial discharge capacity of 1466.4 mAh g−1 at 0.1 C and stable cycle life with a fade rate of 0.03% per cycle over 1000 cycle at 3.0 C. Moreover, a superior areal capacity of 12.84 mAh cm−2 is preserved under high sulfur loading of 14.3 mg cm−2.

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“…Though various transition-metal/metal-free-based SACs implanted carbonaceous matrix or polar compounds demonstrate superior electrocatalytic activity, 171 how to improve the SACs content and precisely tune the inserting position in substrates still need more efforts.…”

Section: Single-atom Catalystsmentioning

confidence: 99%

Designing principles of advanced sulfur cathodes toward practical lithium‐sulfur batteries

Zhang

2022

SusMat

109

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As one of the most promising candidates for next-generation energy storage systems, lithium-sulfur (Li-S) batteries have gained wide attention owing to their ultrahigh theoretical energy density and low cost. Nevertheless, their road to commercial application is still full of thorns due to the inherent sluggish redox kinetics and severe polysulfides shuttle. Incorporating sulfur cathodes with adsorbents/catalysts has been proposed to be an effective strategy to address the foregoing challenges, whereas the complexity of sulfur cathodes resulting from the intricate design parameters greatly influences the corresponding energy density, which has been frequently ignored. In this review, the recent progress in design strategies of advanced sulfur cathodes is summarized and the significance of compatible regulation among sulfur active materials, tailored hosts, and elaborate cathode configuration is clarified, aiming to bridge the gap between fundamental research and practical application of Li-S batteries. The representative strategies classified by sulfur encapsulation, host architecture, and cathode configuration are first highlighted to illustrate their synergetic contribution to the electrochemical performance improvement. Feasible integration principles are also proposed to guide the practical design of advanced sulfur cathodes. Finally, prospects and future directions are provided to realize high energy density and long-life Li-S batteries.

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Electrochemical Kinetic Modulators in Lithium–Sulfur Batteries: From Defect‐Rich Catalysts to Single Atomic Catalysts

Cited by 123 publications

References 175 publications

Lithium Atom Surface Diffusion and Delocalized Deposition Propelled by Atomic Metal Catalyst toward Ultrahigh-Capacity Dendrite-Free Lithium Anode

Lithium Atom Surface Diffusion and Delocalized Deposition Propelled by Atomic Metal Catalyst toward Ultrahigh-Capacity Dendrite-Free Lithium Anode

Rational Design of the Lotus‐Like N‐Co₂VO₄‐Co Heterostructures with Well‐Defined Interfaces in Suppressing the Shuttle Effect and Dendrite Growth in Lithium–Sulfur Batteries

Designing principles of advanced sulfur cathodes toward practical lithium‐sulfur batteries

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Electrochemical Kinetic Modulators in Lithium–Sulfur Batteries: From Defect‐Rich Catalysts to Single Atomic Catalysts

Cited by 123 publications

References 175 publications

Lithium Atom Surface Diffusion and Delocalized Deposition Propelled by Atomic Metal Catalyst toward Ultrahigh-Capacity Dendrite-Free Lithium Anode

Lithium Atom Surface Diffusion and Delocalized Deposition Propelled by Atomic Metal Catalyst toward Ultrahigh-Capacity Dendrite-Free Lithium Anode

Rational Design of the Lotus‐Like N‐Co2VO4‐Co Heterostructures with Well‐Defined Interfaces in Suppressing the Shuttle Effect and Dendrite Growth in Lithium–Sulfur Batteries

Designing principles of advanced sulfur cathodes toward practical lithium‐sulfur batteries

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Rational Design of the Lotus‐Like N‐Co₂VO₄‐Co Heterostructures with Well‐Defined Interfaces in Suppressing the Shuttle Effect and Dendrite Growth in Lithium–Sulfur Batteries