Unraveling the Voltage Failure Mechanism in Metal Sulfide Anodes for Sodium Storage and Improving Their Long Cycle Life by Sulfur‐Doped Carbon Protection

Wang, Fei; Han, Fei; He, Yezeng; Zhang, Jian; Wu, Haijun; Tao, Ji; Zhang, Chengzhi; Zhang, Fuquan; Liu, Jinshui

doi:10.1002/adfm.202007266

Cited by 69 publications

(56 citation statements)

References 62 publications

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“…Using KFSI/EC + DEC as an example, the representative force responses basically consist of two stages (Figure 5C), including (i) a linear force-increasing region, indicating an elastic process, and (ii) a quasi-constant force region, corresponding to an ideal plastic process or a yielding process. 55 These results are in line with the force response of elastomers. In contrast, the force responses of the electrode cycled in KPF 6 /EC + DEC are totally different (Figure 5D).…”

Section: Resultssupporting

confidence: 83%

Understanding electrolyte salt chemistry for advanced potassium storage performances of transition‐metal sulfides

Wang

Song

et al. 2022

Carbon Energy

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Molybdenum disulfide/carbon nanotubes assembled by ultrathin nanosheets are synthesized to illustrate the electrolyte salt chemistry via potassium bis-(fluorosulfonyl)imide (KFSI) versus potassium hexafluorophosphate (KPF 6 ).Compared to the case of KPF 6 , the electrochemical performances using KFSI as the electrolyte salt are greatly improved: ~275 mAh g −1 after 15,000 cycles at 1 A g −1 , or ~172 mAh g −1 even at 40 A g −1 . These results represent one of the best performances for the reported anode materials. The enhanced performances could be attributed to the FSI-induced changes in the solvate structures, that is, a large solvation energy, a high lowest unoccupied molecular orbital, and a small bonding dissociation energy of S-F. In this case, a uniform and robust solid-electrolyte interphase (SEI) is produced, improving the mechanical properties and the interface integrity. Then, the uncontrollable fracture and repeated growth of SEI, which always lead to the dissolution of sulfur species and the blockage of charge transfer in the case of KPF 6 , are well inhibited. This similar enhancement works for other sulfides by KFSI, demonstrating the general importance of this electrolyte salt chemistry.

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Section: Resultssupporting

confidence: 83%

Understanding electrolyte salt chemistry for advanced potassium storage performances of transition‐metal sulfides

Wang

Song

et al. 2022

Carbon Energy

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“…At the same time, FeS 2 @NS‐3DHCs are more uneven and rougher than FeS 2 @G@NS‐3DHCs, which hints that Cu has reacted with potassium polysulfides originated from the electrode material. [ 34 ] The elemental mappings of SEM of two cycled electrode materials display the uniform presence of numerous Cu elementals (Figure S9d,e, Supporting Information). However, the Cu content of FeS 2 @NS‐3DHCs electrode material is around five times that of FeS 2 @G@NS‐3DHCs, which suggests that Cu has involved in the charging/discharging, and the phenomenon is more serious when FeS 2 @NS‐3DHCs act as an anode electrode for PIBs.…”

Section: Resultsmentioning

confidence: 99%

“…[ 33 ] In addition, Wang and co‐workers immobilized the dissolved polysulfides via polar carbon–sulfur bonds, thus achieving a stable cycle of 2000 cycles at 5 A g −1 in sodium‐ion batteries. [ 34 ] Obviously, the strong adsorption ability for polysulfides has become the key to inhibiting the shuttle effect of polysulfides. Yet, there is still a lack of in‐depth research to clarify the interaction between FeS 2 and protective shell in the ether‐based electrolyte.…”

Section: Introductionmentioning

confidence: 99%

Engineering Pocket‐Like Graphene–Shell Encapsulated FeS₂: Inhibiting Polysulfides Shuttle Effect in Potassium‐Ion Batteries

Chen

Ding

Bai

et al. 2021

Adv Funct Materials

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Resource‐rich FeS2 is a promising anode for potassium‐ion batteries (PIBs). However, polysulfides emerge due to FeS2 conversion during discharging, which dissolve into the ether‐based electrolyte and cause the continuous capacity degradation in PIBs. To address the polysulfides dissolution in PIBs, a graphene–shell‐encapsulated FeS2 is fabricated and embedded in N/S codoped 3D hollow carbon spheres. As a protective pocket, the graphene–shell can effectively accommodate polysulfides inside the core–shell, inhibiting the polysulfides shuttle effect to enhance cycle stability of electrode. The density functional theory (DFT) calculations demonstrate that graphene–shells have a strong adsorption capacity for polysulfides, and the interfacial interaction between KFeS2 and graphene–shell can boost the K ion mobility. As a result, the composite exhibits superior‐rate properties (524 and 224 mA h g−1 at 0.1 and 8 A g−1, respectively) and long‐term cycle stability. This work demonstrates the promotion and protective effect of the graphene–shell for the FeS2 to storage K from both experimental and computational perspectives. These research outputs can provide guidance for designing other metal‐based sulfide electrodes for PIBs.

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“…[24,37,38] A pair of redox peaks near 0.01 V might be attributed to the pseudo-capacitive process at the interface of the formed nanoparticles. [39] In the second cycle, the cathodic peaks at ≈1.24 and 0.9 V shift positively to ≈1.58 and 1.01 V, and the anodic peaks at ≈1.89 and 2.1 V shift negatively to ≈1.82 and 1.96 V, which are caused by the enhanced electrochemical kinetics of electrode after the first cycle owing to the formation optimized material structure. The profiles of subsequent cycles remained steady and overlapped well, indicating that the electrochemical reaction was reversible and stable.…”

Section: Electrochemical Performancementioning

confidence: 91%

Enhancing the Electrochemical Performance of Sodium‐Ion Batteries by Building Optimized NiS₂/NiSe₂ Heterostructures

Cui

Liu

et al. 2021

Small

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NiS1.23Se0.77 nanosheets closely attached to the internal surface of hollow mesoporous carbon sphere (HMCS) to form a NiS1.23Se0.77 nanosheets embedded in HMCS (NSSNs@HMCS) composite as the anode of sodium ion batteries (SIBs) is reported by a facile synthesis route. The anode exhibits a superior reversible capacity (520 mAh g−1 at 0.1 A g−1), impressive coulombic efficiency (CE) of up to 95.3%, a high rate capacity (353 mAh g−1 at 5.0 A g−1), excellent capacity retention at high current density (95.6%), and high initial coulombic efficiency (ICE) (95.1%). Firstly, the highest ICE for NiS2/NiSe2‐based anode can be ascribed to ultrathin layered structure of NiS1.23Se0.77 nanosheet and highly efficient electron transfer between the active material and HMCS. Secondly, the optimized NiS2/NiSe2 heterostructure at the nanoscale of the inside HMCS is formed after the first discharge/charge cycles, which can provide rich heterojunction interfaces/boundaries of sulfide/selenides to offer faster Na+ pathways, decrease the Na+ diffusion barriers, increase electronic conductivity, and limit the dissolution of polysulfides or polyselenides in the electrolyte. Finally, the hollow structure of the HMCS accommodates the volume expansion, prevents the pulverization and aggregation issues of composite materials, which can also promote outstanding electrochemical performance.

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Unraveling the Voltage Failure Mechanism in Metal Sulfide Anodes for Sodium Storage and Improving Their Long Cycle Life by Sulfur‐Doped Carbon Protection

Cited by 69 publications

References 62 publications

Understanding electrolyte salt chemistry for advanced potassium storage performances of transition‐metal sulfides

Understanding electrolyte salt chemistry for advanced potassium storage performances of transition‐metal sulfides

Engineering Pocket‐Like Graphene–Shell Encapsulated FeS₂: Inhibiting Polysulfides Shuttle Effect in Potassium‐Ion Batteries

Enhancing the Electrochemical Performance of Sodium‐Ion Batteries by Building Optimized NiS₂/NiSe₂ Heterostructures

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Unraveling the Voltage Failure Mechanism in Metal Sulfide Anodes for Sodium Storage and Improving Their Long Cycle Life by Sulfur‐Doped Carbon Protection

Cited by 69 publications

References 62 publications

Understanding electrolyte salt chemistry for advanced potassium storage performances of transition‐metal sulfides

Understanding electrolyte salt chemistry for advanced potassium storage performances of transition‐metal sulfides

Engineering Pocket‐Like Graphene–Shell Encapsulated FeS2: Inhibiting Polysulfides Shuttle Effect in Potassium‐Ion Batteries

Enhancing the Electrochemical Performance of Sodium‐Ion Batteries by Building Optimized NiS2/NiSe2 Heterostructures

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Product

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Engineering Pocket‐Like Graphene–Shell Encapsulated FeS₂: Inhibiting Polysulfides Shuttle Effect in Potassium‐Ion Batteries

Enhancing the Electrochemical Performance of Sodium‐Ion Batteries by Building Optimized NiS₂/NiSe₂ Heterostructures