Interface chemistry engineering in electrode systems for electrochemical energy storage

Yu, Lei; Qian, Zhen; Shi, Nannan; Liu, Qi; Wang, Jun; Jing, Xiaoyan

doi:10.1039/c4ra03616f

Cited by 7 publications

(5 citation statements)

References 197 publications

(231 reference statements)

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“…The interfacial stability between the lithium electrode and the CEM could be evaluated using impedance resistance, which reflects the diffusion of lithium ions across the electrolyte/Li interfaces and influences the cycling life and C-rate capability of the cells [36,41]. …”

Section: Interfacial Stability Of Cems/limentioning

confidence: 99%

Composite electrolyte membranes incorporating viscous copolymers with cellulose for high performance lithium-ion batteries

Zhang

Xia

et al. 2016

Journal of Membrane Science

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Section: Interfacial Stability Of Cems/limentioning

confidence: 99%

Composite electrolyte membranes incorporating viscous copolymers with cellulose for high performance lithium-ion batteries

Zhang

Xia

et al. 2016

Journal of Membrane Science

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“…However, the electrode is a completed system, the electrochemical performance not only depends on Li 4 Ti 5 O 12 active material, but also on the other component, such as the current collector. The current collector interface design as well as the interface interacting between the active material and the conductive substrate plays a key role in electrochemical process . Therefore, it could be an effective method to improve the electrochemical performance of Li 4 Ti 5 O 12 through modifying the Cu current collector.…”

Section: Introductionmentioning

confidence: 99%

“…The current collector interface design as well as the interface interacting between the active material and the conductive substrate plays a key role in electrochemical process. 25 Therefore, it could be an effective method to improve the electrochemical performance of Li 4 Ti 5 O 12 through modifying the Cu current collector.…”

Section: Introductionmentioning

confidence: 99%

Effect of Graphene Modified Cu Current Collector on the Performance of Li₄Ti₅O₁₂Anode for Lithium-Ion Batteries

Jiang

Nie

Ding

et al. 2016

ACS Appl. Mater. Interfaces

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Interface design between current collector and electroactive materials plays a key role in the electrochemical process for lithium-ion batteries. Here, a thin graphene film has been successfully synthesized on the surface of Cu current collector by a large-scale low-pressure chemical vapor deposition (LPCVD) process. The modified Cu foil was used as a current collector to support spinel LiTiO anode directly. Electrochemical test results demonstrated that graphene coating Cu foil could effectively improve overall Li storage performance of LiTiO anode. Especially under high current rate (e.g., 10 C), the LiTiO electrode using modified current collector maintained a favorable capacity, which is 32% higher than that electrode using bare current collector. In addition, cycling performance has been improved using the new type current collector. The enhanced performance can be attributed to the reduced internal resistance and improved charge transfer kinetics of graphene film by increasing electron collection and decreasing lithium ion interfacial diffusion. Furthermore, the graphene film adhered on the Cu foil surface could act as an effective protective film to avoid oxidization, which can effectively improve chemical stability of Cu current collector.

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“…With the rapid development of materials design strategies and synthesis techniques, great progress has been achieved in the fabrication of transition metal oxides with various nanostructures and enhanced electrochemical performance. [1c,3a,8c,145] As anode materials for LIBs and NIBs, metal oxides typically store Li + and Na + via a redox conversion reaction, which results in the reversible formation of metallic nanoparticles dispersed intimately within the Li 2 O matrix that maintain electronic conductivity. [3c,8c,8e,143d,146] However, it is well known that metal oxides go through an electrochemically induced volume expansion upon the formation of Li 2 O during initial charging …”

Section: Multi‐electron Reactions In Libs and Nibsmentioning

confidence: 99%

Advanced High Energy Density Secondary Batteries with Multi‐Electron Reaction Materials

et al. 2016

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Secondary batteries have become important for smart grid and electric vehicle applications, and massive effort has been dedicated to optimizing the current generation and improving their energy density. Multi‐electron chemistry has paved a new path for the breaking of the barriers that exist in traditional battery research and applications, and provided new ideas for developing new battery systems that meet energy density requirements. An in‐depth understanding of multi‐electron chemistries in terms of the charge transfer mechanisms occuring during their electrochemical processes is necessary and urgent for the modification of secondary battery materials and development of secondary battery systems. In this Review, multi‐electron chemistry for high energy density electrode materials and the corresponding secondary battery systems are discussed. Specifically, four battery systems based on multi‐electron reactions are classified in this review: lithium‐ and sodium‐ion batteries based on monovalent cations; rechargeable batteries based on the insertion of polyvalent cations beyond those of alkali metals; metal–air batteries, and Li–S batteries. It is noted that challenges still exist in the development of multi‐electron chemistries that must be overcome to meet the energy density requirements of different battery systems, and much effort has more effort to be devoted to this.

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Interface chemistry engineering in electrode systems for electrochemical energy storage

Abstract: In this review, we introduce two powerful strategies for well-controlled interface. Interface chemistry engineering in electrode systems for electrochemical energy storage needs to integrate individual materials components to interface design and optimization.

Cited by 7 publications

References 197 publications

Composite electrolyte membranes incorporating viscous copolymers with cellulose for high performance lithium-ion batteries

Composite electrolyte membranes incorporating viscous copolymers with cellulose for high performance lithium-ion batteries

Effect of Graphene Modified Cu Current Collector on the Performance of Li₄Ti₅O₁₂Anode for Lithium-Ion Batteries

Advanced High Energy Density Secondary Batteries with Multi‐Electron Reaction Materials

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Interface chemistry engineering in electrode systems for electrochemical energy storage

Abstract: In this review, we introduce two powerful strategies for well-controlled interface. Interface chemistry engineering in electrode systems for electrochemical energy storage needs to integrate individual materials components to interface design and optimization.

Cited by 7 publications

References 197 publications

Composite electrolyte membranes incorporating viscous copolymers with cellulose for high performance lithium-ion batteries

Composite electrolyte membranes incorporating viscous copolymers with cellulose for high performance lithium-ion batteries

Effect of Graphene Modified Cu Current Collector on the Performance of Li4Ti5O12Anode for Lithium-Ion Batteries

Advanced High Energy Density Secondary Batteries with Multi‐Electron Reaction Materials

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Effect of Graphene Modified Cu Current Collector on the Performance of Li₄Ti₅O₁₂Anode for Lithium-Ion Batteries