Recent Advances in Solid-Electrolyte Interphase for Li Metal Anode

He, Dafang; Lu, Junhong; He, Guangyu; Chen, Haiqun

doi:10.3389/fchem.2022.916132

Cited by 11 publications

(7 citation statements)

References 53 publications

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“…The emerging electrical vehicles (EVs) will gradually replace petrol vehicles and become the main means of transport in the near future due to their prominent advantages of energy saving and environmental protection. , Lithium-ion batteries (LIBs) hold the honor of being the “heart” of EVs, and their electrochemical performance determines the cruising range of EVs . Unfortunately, the energy density of LIBs is limited by the traditional intercalation-type cathode materials (such as LiFePO 4 , LiCoO 2 , LiMn 2 O 4 , LiNi x Mn y Co 1– x – y O 2 ), which can only provide an actual theoretical capacity of ∼200 mAh g –1 . − Additionally, the current commercial cobalt- and nickel-based cathode materials have low reserves and high prices, which seriously hinder their commercial application in LIBs.…”

Section: Introductionmentioning

confidence: 99%

Ultrafine FeF₃·0.33H₂O Nanocrystal-Doped Graphene Aerogel Cathode Materials for Advanced Lithium-Ion Batteries

Cao

et al. 2023

Langmuir

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FeF 3 has been extensively studied as an alternative positive material owing to its superior specific capacity and low cost, but the low conductivity, large volume variation, and slow kinetics seriously hinder its commercialization. Here, we propose the in situ growth of ultrafine FeF 3 • 0.33H 2 O NPs on a three-dimensional reduced graphene oxide (3D RGO) aerogel with abundant pores by a facile freeze drying process followed by thermal annealing and fluorination. Within the FeF 3 •0.33H 2 O/RGO composites, the three-dimensional (3D) RGO aerogel and hierarchical porous structure ensure rapid diffusion of electrons/ions within the cathode, enabling good reversibility of FeF 3 . Benefiting from these advantages, a superior cycle behavior of 232 mAh g −1 under 0.1C over 100 cycles as well as outstanding rate performance is achieved. These results provide a promising approach for advanced cathode materials for Li-ion batteries.

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Section: Introductionmentioning

confidence: 99%

Ultrafine FeF₃·0.33H₂O Nanocrystal-Doped Graphene Aerogel Cathode Materials for Advanced Lithium-Ion Batteries

Cao

et al. 2023

Langmuir

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“…A typical SEI layer consists of the reductive decomposition products of electrolyte but plays a role in suppressing further decomposition of electrolyte. [14,15] In AFLMBs with copper metal as the current collector, there is a "native-SEI (N-SEI)" layer forming right after cell assembly, which is composed of some Cu oxides and electrolyte decomposition products. [16] Moreover, an SEI layer forming after applying voltage but before the first Li plating and an SEI layer forming after the first Li stripping are defined as a "pre-SEI" layer and a "subsequent-SEI (s-SEI)" layer, respectively.…”

Section: Introductionmentioning

confidence: 99%

“…A typical SEI layer consists of the reductive decomposition products of electrolyte but plays a role in suppressing further decomposition of electrolyte [14,15] . In AFLMBs with copper metal as the current collector, there is a “native‐SEI (N‐SEI)” layer forming right after cell assembly, which is composed of some Cu oxides and electrolyte decomposition products [16] .…”

Section: Introductionmentioning

confidence: 99%

Li Plating/Stripping Efficiency in Ether‐based Dilute Electrolyte for Anode‐free Lithium‐metal Batteries: Effect of Operating Potential Range on Subsequent SEI Layer Structure

Wang,

Noguchi

2023

Batteries & Supercaps

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Anode‐free lithium‐metal batteries (AFLMBs) are regarded as a promising candidate for next‐generation batteries due to a great enhancement of energy density over lithium‐metal anode batteries. However, unstable solid‐electrolyte interface (SEI) formation accompanied by lithium dendrite growth and electrolyte decomposition causes low Coulombic efficiencies. This study explores the effect of different operating potential ranges on SEI layer structure and further on Li plating/stripping efficiency in the dilute LiTFSI/TEGDME electrolyte in an AFLMB anode half‐cell configuration. Cyclic voltammetry analyses reveal the existence of an “oxidative subsequent SEI” formation process (named as OSS) and the improved Li plating/stripping efficiency by blocking reaction OSS, which is further verified by quartz crystal microbalance analysis regarding the insight of such an improvement. XPS depth‐profile analysis confirms the formation of the Li2O‐ and lithium‐sulfur compounds‐based subsequent SEI layers when the OSS process is blocked, which guarantees the improved stability of Li plating/stripping. A hypothesis is proposed to discuss possible electrochemical reactions via OSS process by combining in situ surface‐enhanced Raman spectroscopy analysis. These results together suggested the importance of adjusting operating potential range in a proper manner to achieve a better performance in Li plating/stripping in AFLMB configuration.

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“…The SEI layer generated during the electrochemical cycling of the battery mainly prevents the reaction between the electrolyte and the electrode material. However, due to its high reactivity, lithium metal is extremely easy to react with the electrolyte, which leads to the continuous rupture and reconstruction of the SEI layer during cycling, increases the impedance of the battery, and reduces the cycling efficiency [29]. Conventional commercial lithium-ion batteries work by embedding and dragging lithium ions back and forth in the graphite anode during charging and discharging [30].…”

Section: Introductionmentioning

confidence: 99%

Coatings on Lithium Battery Separators: A Strategy to Inhibit Lithium Dendrites Growth

Cheng,

Tan,

et al. 2023

Molecules

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Lithium metal is considered a promising anode material for lithium secondary batteries by virtue of its ultra-high theoretical specific capacity, low redox potential, and low density, while the application of lithium is still challenging due to its high activity. Lithium metal easily reacts with the electrolyte during the cycling process, resulting in the continuous rupture and reconstruction of the formed SEI layer, which reduces the cycling reversibility. On the other hand, repeated lithium plating/stripping processes can lead to uncontrolled growth of lithium dendrites and a series of safety issues caused by short-circuiting of the battery. Currently, modification of the battery separator layer is a good strategy to inhibit lithium dendrite growth, which can improve the Coulombic efficiency in the cycle. This paper reviews the preparation, behavior, and mechanism of the modified coatings using metals, metal oxides, nitrides, and other materials on the separator to inhibit the formation of lithium dendrites and achieve better stable electrochemical cycles. Finally, further strategies to inhibit lithium dendrite growth are proposed.

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Recent Advances in Solid-Electrolyte Interphase for Li Metal Anode

Cited by 11 publications

References 53 publications

Ultrafine FeF₃·0.33H₂O Nanocrystal-Doped Graphene Aerogel Cathode Materials for Advanced Lithium-Ion Batteries

Ultrafine FeF₃·0.33H₂O Nanocrystal-Doped Graphene Aerogel Cathode Materials for Advanced Lithium-Ion Batteries

Li Plating/Stripping Efficiency in Ether‐based Dilute Electrolyte for Anode‐free Lithium‐metal Batteries: Effect of Operating Potential Range on Subsequent SEI Layer Structure

Coatings on Lithium Battery Separators: A Strategy to Inhibit Lithium Dendrites Growth

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Recent Advances in Solid-Electrolyte Interphase for Li Metal Anode

Cited by 11 publications

References 53 publications

Ultrafine FeF3·0.33H2O Nanocrystal-Doped Graphene Aerogel Cathode Materials for Advanced Lithium-Ion Batteries

Ultrafine FeF3·0.33H2O Nanocrystal-Doped Graphene Aerogel Cathode Materials for Advanced Lithium-Ion Batteries

Li Plating/Stripping Efficiency in Ether‐based Dilute Electrolyte for Anode‐free Lithium‐metal Batteries: Effect of Operating Potential Range on Subsequent SEI Layer Structure

Coatings on Lithium Battery Separators: A Strategy to Inhibit Lithium Dendrites Growth

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Ultrafine FeF₃·0.33H₂O Nanocrystal-Doped Graphene Aerogel Cathode Materials for Advanced Lithium-Ion Batteries

Ultrafine FeF₃·0.33H₂O Nanocrystal-Doped Graphene Aerogel Cathode Materials for Advanced Lithium-Ion Batteries