Boosting Polysulfide Conversion in Lithium–Sulfur Batteries by Cobalt-Doped Vanadium Nitride Microflowers

Cheng, Zhaozhuang; Wang, Yaxiong; Zhang, Wenjun; Xu, Ming

doi:10.1021/acsaem.0c00205

Cited by 38 publications

(34 citation statements)

References 53 publications

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“…The strong peaks at 36.6 o and 42.6 o refer to the (111) and (200) plane, respectively, in TiN lattice. [ 26,27 ] Noticeably, these peaks witness a continuous positive shift along with the increase of V content (from TVN‐5 to TVN‐4 and TVN‐3), suggesting a reduction in interplanar spacing. However, it should be noted that these peaks are relatively closer to TiN rather than VN, signifying that the TVNs are still dominated by TiN‐based lattice framework but with structural distortion to a varying extent.…”

Section: Resultsmentioning

confidence: 99%

Dissolving Vanadium into Titanium Nitride Lattice Framework for Rational Polysulfide Regulation in Li–S Batteries

Shang

Wei

et al. 2020

Advanced Energy Materials

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Rational regulation of host–guest interactive chemistry is of great significance but has not yet effectively been applied in lithium–sulfur (Li–S) batteries. Herein, a unique titanium vanadium nitride (TVN) solid solution fabric is developed as an ideal platform for fine structure modulation towards efficient and durable sulfur electrochemistry. The dissolution of V into the TiN lattice framework is shown to subtly tailor the coordinative and electronic structures of Ti and V, tuning their respective chemical affinity to sulfur species. Consequently, the optimized Ti–V interplay renders the highest overall polysulfide adsorpabiltiy, and contributes to strong sulfur immobilization and fast reaction kinetics. The resultant Li–S cells realize an outstanding cyclability with high capacity retention of 97.7% after 400 cycles. Moreover, reversible areal capacity over 6.11 mAh cm−2 can be sustained under a high sulfur loading of 6.0 mg cm−2 and a limited electrolyte concentration of 6.5 mL g−1. This work provides a novel strategic perspective for the rational regulation of fine structure towards superior Li–S batteries and beyond.

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Section: Resultsmentioning

confidence: 99%

Dissolving Vanadium into Titanium Nitride Lattice Framework for Rational Polysulfide Regulation in Li–S Batteries

Shang

Wei

et al. 2020

Advanced Energy Materials

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“…[ 23,24 ] To overcome current cathode limitations, metal‐based compounds and metal‐organic frameworks have been added to strengthen the chemical interaction with LiPS and reduce the shuttle effect. [ 25–30 ] Among the tested metal compounds, sulfides such as MoS 2 , VS 2 , CoS 2 , Ni 3 S 2 , and Sb 2 S 3 , have demonstrated particularly strong sulfiphilic ability toward LiPS trapping and low lithiation voltages. [ 31–36 ] However, cathodes based on metal sulfides are generally characterized by moderate electrical conductivities, limited sulfur utilization, insufficient cycling stability, and low rate capabilities.…”

Section: Introductionmentioning

confidence: 99%

Enhanced Polysulfide Conversion with Highly Conductive and Electrocatalytic Iodine‐Doped Bismuth Selenide Nanosheets in Lithium–Sulfur Batteries

Yang

Biendicho

et al. 2022

Adv Funct Materials

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The shuttling behavior and sluggish conversion kinetics of intermediate lithium polysulfides (LiPS) represent the main obstacles to the practical application of lithium–sulfur batteries (LSBs). Herein, an innovative sulfur host is proposed, based on an iodine‐doped bismuth selenide (I‐Bi2Se3), able to solve these limitations by immobilizing the LiPS and catalytically activating the redox conversion at the cathode. The synthesis of I‐Bi2Se3 nanosheets is detailed here and their morphology, crystal structure, and composition are thoroughly. Density‐functional theory and experimental tools are used to demonstrate that I‐Bi2Se3 nanosheets are characterized by a proper composition and micro‐ and nano‐structure to facilitate Li+ diffusion and fast electron transportation, and to provide numerous surface sites with strong LiPS adsorbability and extraordinary catalytic activity. Overall, I‐Bi2Se3/S electrodes exhibit outstanding initial capacities up to 1500 mAh g−1 at 0.1 C and cycling stability over 1000 cycles, with an average capacity decay rate of only 0.012% per cycle at 1 C. Besides, at a sulfur loading of 5.2 mg cm−2, a high areal capacity of 5.70 mAh cm−2 at 0.1 C is obtained with an electrolyte/sulfur ratio of 12 µL mg−1. This work demonstrated that doping is an effective way to optimize the metal selenide catalysts in LSBs.

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“…Compared with non-polar carbons, nanostructured polar inorganic compounds such as metal oxides, [95,96] sulfides, [97][98][99][100][101] carbides, [102,103] and nitrides [104][105][106] et al (Figure 5a-e) have gradually ascended as coating materials toward sulfur cathodes. Among them, metal sulfides attract particular interest due to strong sulfiphilicity together with multiple thermodynamically stable crystal structures and abundant reactive sites.…”

Section: Nano Metal Sulfides(oxide)mentioning

confidence: 99%

“…Compared with non‐polar carbons, nanostructured polar inorganic compounds such as metal oxides, [95,96] sulfides, [97–101] carbides, [102,103] and nitrides [104–106] et al. (Figure 5a–e) have gradually ascended as coating materials toward sulfur cathodes.…”

Section: Nanomaterials For Interface Of Liquid Electrolyte Systemmentioning

confidence: 99%

Recent Progress in High‐Performance Lithium Sulfur Batteries: The Emerging Strategies for Advanced Separators/Electrolytes Based on Nanomaterials and Corresponding Interfaces

Wang

Deng

Wei

et al. 2021

Chemistry An Asian Journal

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Lithium-sulfur (LiÀ S) batteries, possessing excellent theoretical capacities, low cost and nontoxicity, are one of the most promising energy storage battery systems. However, poor conductivity of elemental S and the "shuttle effect" of lithium polysulfides hinder the commercialization of LiÀ S batteries. These problems are closely related to the interface problems between the cathodes, separators/electrolytes and anodes. The review focuses on interface issues for advanced separators/electrolytes based on nanomaterials in LiÀ S batteries. In the liquid electrolyte systems, electrolytes/separators and electrodes system can be decorated by nano materials coating for separators and electrospinning nanofiber separators. And, interface of anodes and electrolytes/ separators can be modified by nano surface coating, nano composite metal lithium and lithium nano alloy, while the interface between cathodes and electrolytes/separators is designed by nano metal sulfide, nanocarbon-based and other nano materials. In all solid-state electrolyte systems, the focus is to increase the ionic conductivity of the solid electrolytes and reduce the resistance in the cathode/polymer electrolyte and Li/electrolyte interfaces through using nanomaterials. The basic mechanism of these interface problems and the corresponding electrochemical performance are discussed. Based on the most critical factors of the interfaces, we provide some insights on nanomaterials in high-performance liquid or state LiÀ S batteries in the future.

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Boosting Polysulfide Conversion in Lithium–Sulfur Batteries by Cobalt-Doped Vanadium Nitride Microflowers

Cited by 38 publications

References 53 publications

Dissolving Vanadium into Titanium Nitride Lattice Framework for Rational Polysulfide Regulation in Li–S Batteries

Dissolving Vanadium into Titanium Nitride Lattice Framework for Rational Polysulfide Regulation in Li–S Batteries

Enhanced Polysulfide Conversion with Highly Conductive and Electrocatalytic Iodine‐Doped Bismuth Selenide Nanosheets in Lithium–Sulfur Batteries

Recent Progress in High‐Performance Lithium Sulfur Batteries: The Emerging Strategies for Advanced Separators/Electrolytes Based on Nanomaterials and Corresponding Interfaces

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