Enhanced Electrochemical Performance of Ni‐Rich Layered Cathode Materials by using LiPF<sub>6</sub> as a Cathode Additive

Zhang, Sheng S.; Fan, Xiulin; Chun-sheng, Wang

doi:10.1002/celc.201801858

Cited by 49 publications

(49 citation statements)

References 47 publications

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“…Furthermore, Li salts can also be used to improve NMC-based cell performances. For example, LiPF 6 can react with excessive alkaline Li on the surfaces of cathode particles to produce chemically stable Li 3 PO 4 and LiF, and significantly suppress parasitic reactions caused by excessive Li [152]. Surface coating is another commonly used strategy to separate NMC cathode surfaces from electrolytes [15], and atom substitution has also been reported to be effective in enhancing the performance of mitigated Ni-rich NMC-based LIBs.…”

Section: Ni-rich Nmc-based Cathodesmentioning

confidence: 99%

Degradation Mechanisms and Mitigation Strategies of Nickel-Rich NMC-Based Lithium-Ion Batteries

Yuan

Zhang

et al. 2019

Electrochem. Energ. Rev.

449

383

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The demand for lithium-ion batteries (LIBs) with high mass-specific capacities, high rate capabilities and long-term cyclabilities is driving the research and development of LIBs with nickel-rich NMC (LiNi x Mn y Co 1−x−y O 2 , x ⩾ 0.5 ) cathodes and graphite (Li x C 6 ) anodes. Based on this, this review will summarize recently reported and widely recognized studies of the degradation mechanisms of Ni-rich NMC cathodes and graphite anodes. And with a broad collection of proposed mechanisms on both atomic and micrometer scales, this review can supplement previous degradation studies of Ni-rich NMC batteries. In addition, this review will categorize advanced mitigation strategies for both electrodes based on different modifications in which Ni-rich NMC cathode improvement strategies involve dopants, gradient layers, surface coatings, carbon matrixes and advanced synthesis methods, whereas graphite anode improvement strategies involve surface coatings, charge/discharge protocols and electrolyte volume estimations. Electrolyte components that can facilitate the stabilization of anodic solid electrolyte interfaces are also reviewed, and trade-offs between modification techniques as well as controversies are discussed for a deeper understanding of the mitigation strategies of Ni-rich NMC/graphite LIBs. Furthermore, this review will present various physical and electrochemical diagnostic tools that are vital in the elucidation of degradation mechanisms during operation to supplement future degradation studies. Finally, this review will summarize current research focuses and propose future research directions.

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Section: Ni-rich Nmc-based Cathodesmentioning

confidence: 99%

Degradation Mechanisms and Mitigation Strategies of Nickel-Rich NMC-Based Lithium-Ion Batteries

Yuan

Zhang

et al. 2019

Electrochem. Energ. Rev.

449

383

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“…However, although increased nickel content in Ni-rich cathode materials enables them to deliver higher capacity, more residual lithium compounds (RLCs) will be formed on their surface. The RLC mainly contains Li 2 O, Li 2 O 2 , LiOH, LiHCO 3 , and Li 2 CO 3 (Liu et al, 2004;Kim et al, 2006;Bichon et al, 2019;Zhang et al, 2019), which origins from the vestigial of lithium salts and spontaneous reduction reaction of Ni 3+ during the synthesis and storage process (Junhyeok et al, 2018). In detail, excess 5 mol% lithium salts are usually applied to compensate the evaporation loss during high-temperature calcination process (Liang et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

Clean the Ni-Rich Cathode Material Surface With Boric Acid to Improve Its Storage Performance

Chen

et al. 2020

Front. Chem.

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The existence of residual lithium compounds (RLCs) on the surface of layered Ni-rich materials will deteriorate the electrochemical properties and cause safety problem. This work presents an effective surface washing method to remove the RLCs from LiNi 0.90 Co 0.06 Mn 0.04 O 2 material surface, via ethyl alcohol solution that contains low concentration of boric acid. It is a low-cost process because the filter liquor can be recycled. The optimal parameters including washing time, boric acid concentration, and solid-liquid ratio were systematically studied. It has been determined by powder pH and Fourier transform infrared spectra results that the amount of RLCs was reduced effectively, and the storage performance was significantly enhanced for the washed samples. The 150th capacity retentions after storing had increased from 68.39% of pristine material to 85.46-94.84% of the washed materials. The performance enhancements should be ascribed to the surface washing process, which removed not only the RLCs, but also the loose primary particles effectively.

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“…Because of this, they are known as rocking chair batteries. Lithium ion battery (LIB), with its high energy density, high open circuit voltage and large output power, etc., had been applied commercially for a long time [5,6] . However, nor is LIB without its disadvantages.…”

Section: Introductionmentioning

confidence: 99%

Hierarchical Lamellar‐Structured MnO₂@graphene for High Performance Li, Na and K ion Batteries

Zhang

Jin

et al. 2020

ChemistrySelect

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Finding suitable electrode materials for energy storage devices with large ions like Na+ and K+ is notoriously difficult. Herein, MnO2@graphene with hierarchical lamellar structure has be synthesized. The flower‐like lamellar‐structured MnO2 and nanosheets of graphene combine together to form the composite with vast space for large ions to transport and store, as well as huge surface area for reactions. Sandwiched between graphene nanosheets, electrical conductivity and mechanical properties of MnO2 are highly enhanced, enabling it to withstand large current shock and long time cycling. In Li, Na and K ion batteries, MnO2@graphene all shows excellent electrochemical performance. Also, when coupled with liquid K−Na anode, MnO2@graphene displays better performance than with solid K anode, indicating its great potential at dendrite‐free K ion battery. MnO2@graphene promotes the exploitation of more suitable electrode materials for alkali ion batteries, deepens understanding of their inner mechanisms, and boosts their commercialization.

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Enhanced Electrochemical Performance of Ni‐Rich Layered Cathode Materials by using LiPF₆ as a Cathode Additive

Cited by 49 publications

References 47 publications

Degradation Mechanisms and Mitigation Strategies of Nickel-Rich NMC-Based Lithium-Ion Batteries

Degradation Mechanisms and Mitigation Strategies of Nickel-Rich NMC-Based Lithium-Ion Batteries

Clean the Ni-Rich Cathode Material Surface With Boric Acid to Improve Its Storage Performance

Hierarchical Lamellar‐Structured MnO₂@graphene for High Performance Li, Na and K ion Batteries

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Enhanced Electrochemical Performance of Ni‐Rich Layered Cathode Materials by using LiPF6 as a Cathode Additive

Cited by 49 publications

References 47 publications

Degradation Mechanisms and Mitigation Strategies of Nickel-Rich NMC-Based Lithium-Ion Batteries

Degradation Mechanisms and Mitigation Strategies of Nickel-Rich NMC-Based Lithium-Ion Batteries

Clean the Ni-Rich Cathode Material Surface With Boric Acid to Improve Its Storage Performance

Hierarchical Lamellar‐Structured MnO2@graphene for High Performance Li, Na and K ion Batteries

Contact Info

Product

Resources

About

Enhanced Electrochemical Performance of Ni‐Rich Layered Cathode Materials by using LiPF₆ as a Cathode Additive

Hierarchical Lamellar‐Structured MnO₂@graphene for High Performance Li, Na and K ion Batteries